DIPLOMARBEIT
Titel der Diplomarbeit
Humoral and cellular characterization of minor allergens in birch pollen
Verfasser
Christian Walterskirchen
angestrebter akademischer Grad
Magister der Naturwissenschaften (Mag.rer.nat.)
Wien, 2012
Studienkennzahl lt. Studienblatt:
A 441
Studienrichtung lt. Studienblatt:
Diplomstudium Genetik - Mikrobiologie
Betreuer: o. Univ. Prof. Dr. Thomas Decker
1
2
Danksagung
Ich möchte mich bei meiner Betreuerin Barbara Bohle bedanken, die mir die Möglichkeit
gegeben hat in ihrem Labor zu arbeiten und mich in allen belangen umfangreich unterstützt
hat.
Weiters möchte ich all meinen Kollegen und Kolleginnen im Labor, im speziellen Stephan
Deifl, Birgit Nagl und Sonja Mutschlechner, für die technischen Einschulungen und für die
angenehme Arbeitsatmosphäre danken.
Vielen Dank auch an meine Eltern und an meine Partnerin Astrid, die mich immer in allen Lebenslagen unterstützt haben und ohne die dieses Studium nicht möglich gewesen wäre.
3
Content
Abstract ...................................................................................................................................... 7
Introduction ................................................................................................................................ 8
The immune system ............................................................................................................... 8
The innate immune system ................................................................................................ 8
The adaptive immune system ............................................................................................ 8
T-cell cloning ..................................................................................................................... 12
Birch pollen allergy / Type I hypersensitivity ....................................................................... 13
Sensitization phase ........................................................................................................... 13
Immediate and late reaction ............................................................................................ 14
Birch pollen allergens ........................................................................................................... 15
Bet v 1 – the major birch pollen allergen ......................................................................... 16
Minor allergens .................................................................................................................... 17
Bet v 2 ............................................................................................................................... 17
Bet v 3 ............................................................................................................................... 17
Bet v 4 ............................................................................................................................... 18
Bet v 6 ............................................................................................................................... 18
Bet v 7 ............................................................................................................................... 18
Aims of the study.................................................................................................................. 19
Materials and Methods ............................................................................................................ 20
Cloning .................................................................................................................................. 20
Minor Birch pollen allergen DNA sequence ..................................................................... 20
DNA digestion ................................................................................................................... 20
Dephosphorylation of digested vectors ........................................................................... 20
Agarose gel electrophoresis ............................................................................................. 20
Gel extraction of separated DNA samples using Quia Quick gel extraction kit ............... 21
4
DNA Ligation ..................................................................................................................... 22
Transformation in chemically competent E.coli strains ................................................... 22
Plasmid preparation from E.coli using QUIAprep spin Miniprep Kit ................................ 23
Protein expression and purification ..................................................................................... 24
Testexpression in E.coli BL21 ........................................................................................... 24
Separation of protein samples by SDS PAGE ................................................................... 25
Coomassie staining ........................................................................................................... 26
Western Blot..................................................................................................................... 26
Expression of recombinant birch pollen allergens ........................................................... 28
Purification of His tagged proteins by Ni affinity chromatography ................................. 29
Preparation of the dialysis membrane ............................................................................. 30
Dialysis of eluted fractions ............................................................................................... 30
Endotoxin removal ........................................................................................................... 31
Bicinchoninic acid (BCA) assay ......................................................................................... 32
Determine endotoxin levels (LAL assay) .......................................................................... 33
Confirmation of IgE binding (ELISA) ................................................................................. 34
Tissue culture ....................................................................................................................... 35
Patients with birch pollen allergy ..................................................................................... 35
PBMC isolation by Ficoll gradient ..................................................................................... 35
Stimulation of PBMCs (Primary response) ...................................................................... 36
Generation of T-cell lines ................................................................................................. 36
T-cell line .......................................................................................................................... 37
Specific stimulation of T-cell lines .................................................................................... 37
Epitope mapping of Bet v 1-specific TCCs ........................................................................ 38
Cloning by limiting dilution .............................................................................................. 38
Specific stimulation of T-cell clones ................................................................................. 39
5
Cytokine measurement .................................................................................................... 39
Characterization of TCCs by flow cytometry .................................................................... 40
mRNA isolation using RNeasy kit (Quiagen)..................................................................... 41
Transcription to cDNA using the GeneAmp RNA PCR kit ................................................. 42
T-cell receptor family typing ............................................................................................ 43
Storage of T-cell clones .................................................................................................... 44
Results ...................................................................................................................................... 45
Production and purification of birch pollen allergens ......................................................... 45
Cloning of DNA encoding birch pollen allergens in the pHIS parallel 2 vector ................ 45
Testexpression of birch pollen allergens in E.coli BL21 (DE3)pLysS ................................. 47
Large scale expression and affinity purification of recombinant birch pollen proteins .. 55
Endotoxin removal and determination of endotoxin levels of recombinant proteins .... 59
Humoral and cellular characterization of minor birch pollen allergens .............................. 60
IgE binding capacity of recombinant allergens ................................................................ 60
Proliferative responses of PBMC to recombinant birch pollen allergens ........................ 62
Isolation and characterization of birch pollen specific T-cell clones ................................... 67
Allergen induced proliferation of T-cell clones ................................................................ 67
Th subsets of allergen specific T-cell clones ..................................................................... 71
Surface marker expression of allergen specific T-cell clones ........................................... 73
TCR family typing .............................................................................................................. 76
Discussion ................................................................................................................................. 78
References ............................................................................................................................ 82
Appendix ................................................................................................................................... 88
Zusammenfassung .................................................................................................................... 88
Abstract .................................................................................................................................... 90
Abbreviations ........................................................................................................................... 91
6
Media and buffer .................................................................................................................. 92
Curriculum vitae ....................................................................................................................... 95
7
Abstract
Allergic diseases have reached epidemic dimensions in urban areas and reduce the patients´
quality of life. Pollen from wind pollinated plants is among the most potent allergen sources.
Pollen from the European white birch Betula verrucosa contain the well characterized major
allergen Bet v 1 and several minor allergens which are recognized by less than 50% of birch
pollen-allergic patients.
Diagnosis and therapy of Type I allergy depends on the quality of the employed allergen
extracts. Disadvantages such as batch to batch variability or standardization of the
concentration of different components in allergen extracts may be overcome by the use of
recombinant allergens.
The major aims of this thesis were i) the expression, purification and characterization of the
minor birch pollen allergens Bet v 3, Bet v 4, Bet v 6, Bet v 7 and ii) the isolation and
characterization of T-cell clones (TCC) specific for proteins in birch pollen.
All minor allergens were expressed in E.coli with a His-tag and purified by Ni- affinity
chromatography. The LPS content was reduced to negligible levels. Correct folding and
allergenicity of the allergens was tested by IgE ELISA experiments conducted with sera from
birch pollen-allergic patients. The ability of the allergens to activate birch pollen-specific T-
cells was assessed in proliferation assays using peripheral blood mononuclear cells (PBMC),
allergen-specific T-cell lines (TCL) and TCC derived from birch pollen-allergic patients. All
recombinant minor allergens were able to bind IgE antibodies and induced proliferation in
PBMC from birch pollen-allergic patients.
Allergen specific TCC were expanded from birch pollen-specific TCL and characterized in
proliferation assays. Various subset-specific markers as well as molecules up regulated by
specific activation were analyzed by flow cytometry. Cytokine levels in the supernatants of
allergen-activated TCC were determined by cytokine bead arrays. Our results demonstrate
that the majority of the TCC isolated from TCL expanded with birch pollen extract were
specific for Bet v 1 and belonged to the TH2-like subset. TCC non-reactive with Bet v 1
belonged to the TH0-subset. None of the clones reacted with the recombinant minor
allergens Bet v 3-7. One TCC was found to be Bet v 2-specific.
In summary, endotoxin free batches of recombinant Bet v 3, Bet v 4, Bet v 6 and Bet v 7 were
produced and their IgE reactivity was confirmed. For the first time, the T-cell activating
capacity of these minor allergens was shown.
In the future, the produced and characterized allergens may help to examine the differences
between Bet v 1 and minor allergens. Furthermore, the stored TCC are valuable in the search
for new proteins with immunological value in birch pollen.
8
Introduction
The immune system
The immune system (IS) is the biological defense mechanism against pathogens and tumor
cells. The general immune response can be divided in the early innate and late adaptive
phase.7
The innate immune system
The innate immune system is the first line of defense and includes epithelial barriers,
phagocytes, natural killer cells (NK-cells), complement proteins and cytokines. Its main
function is the host defense against infection and it further contributes to the removal of
environmental particles, microbial products and allergens.7 Innate immune cells express
germ line-encoded pattern recognition receptors that recognize pathogen associated
molecular patterns (PAMPS) which are shared by many microbes and are often essential for
their survival.8 Toll like receptors (TLRs) are the most important group of pattern recognition
receptors.
Leukocytes of the innate immune system kill ingested microbes by phagocytosis and can
promote inflammation and tissue remodeling at the site of infection. The innate immune
system also influences the adaptive immune response through co-stimulatory molecules and
cytokines7 Interaction of allergens with the innate immune system usually leads to
immunologic tolerance. In patients with allergic predispositions, this interaction triggers
chronic inflammation and the loss of immunologic tolerance.8
The adaptive immune system
Whilst the innate IS exerts a general response against structures bearing PAMPs, the cells of
the adaptive IS are responsible for the specific immune response against pathogens. This
second line of defense, consisting mainly of B- and T-lymphocytes, is confronted with a vast
number of different antigens. Therefore it depends on professional antigen presenting cells
(APCs) which activate and influence T- lymphocytes. These cells then orchestrate the optimal
immune response. Antigens are presented to T-cells by major histocompatibility complex
(MHC) molecules, expressed on the surface of nucleated cells. Class I MHC molecules are
expressed by all cells, MHC II molecules are expressed mainly by antigen presenting cells
(macrophages, dendritic cells...).7 Through genetic recombination and mutation the IS is
able to produce a vast variety of effector cells with receptors that specifically recognize
antigens.9 It can further develop a specific memory which allows a fast immune response to
subsequent exposure of antigen.7
9
B-lymphocytes
B-lymphocytes play a major role in the antibody-mediated humoral immune response. B-
cells develop in the bone marrow and mature B-cells are found primarily in secondary
lymphoid tissues, in lymphoid follicles and in bone marrow. Their main function is the
production of antibodies but they can also function as antigen presenting cells.
B-cells recognize antigens in their native form with their B-cell receptor, a membrane bound
antibody. Antibodies are a type of glycoprotein also called immunoglobulin (Ig). They are
composed of two identical heavy and light chains. Variable regions of the heavy and light
chain on the N-terminus form the antigen binding site. There are five immunoglobulin
isotypes in mammals: IgM, IgA, IgD, IgG and IgE.
In contrast to T-cells, B-lymphocytes don’t need antigen processing prior to their activation.
Activation of naive B-cells by antigen recognition supplemented by TH cell stimulation leads
to differentiation into antibody secreting plasma cells. This can also induce irreversible class
switching from IgM to the other Ig-isotypes, depending on the cytokine milieu provided by
the TH cell. Especially the switch to IgE promoted by IL-4 plays a major role in allergic
reactions.7
T-lymphocytes
T-lymphocytes play a central role in cell to cell mediated immunity and contribute to the
humoral immune response by interacting with B-cells. They mature in the thymus and and
populate secondary lymphoid tissues.
T-cell receptor complex
T-cells recognize processed peptide fragments of foreign proteins in the context of MHC
class I and II molecules (MHC restriction) with their T-cell receptor (TCR). In most T-
lymphocytes, the TCR is a heterodimer composed of two disulfide linked polypeptide chains
called α and β (αβ TCR). These are homologous to the light and heavy chains of
immunoglobulin (Ig) molecules. Each chain consists of a variable (V) and constant (C) region.
The variable regions recognized processed protein antigens as well as polymorphic residues
on the MHC molecule of the antigen presenting cell.7
The γδ TCR is very similar to the common αβ TCR in terms of structure and interaction with
proteins of the TCR complex. This receptor is expressed on less than 5% of all T-cells. These
cells are not MHC restricted and recognize different forms of antigens including lipids and
peptides presented by MHC like molecules.
The TCR heterodimers are non-covalently associated with transmembrane proteins called
CD3 and ζ. These proteins transduce T-cell activating signals into the cell after successful
peptide recognition by the TCR. CD4 and CD8 are coreceptors expressed on the surface of
10
mature T-cells. CD4 is expressed on MHC II restricted T-helper cells and CD8 is found on
MHC I restricted cytotoxic T-cells.
T-lymphocytes consist of functionally distinct populations. They can be distinguished by the
expression of several surface proteins (cluster of differentiation, CD- Molecules).
The major T-cell subsets and their characteristic surface markers, transcriptional regulators
and effector molecules are listed in Table 1.
Table 1: Characteristics of T-cell subtypes. 10
Cytotoxic T- cells
The major effector function of Cytotoxic T- cells (Tc cells) is the killing of infected or
dysfunctional host cells. They express the coreceptor CD8 and recognize antigens displayed
by MHC class I molecules. Activation requires MHC I associated antigen recognition together
with costimulators on APCs (cross presentation) or signals provided by helper T-cells. When
exposed to infected cells, the response of differentiated cytotoxic T-lymphocytes involves
the release of cytoplasmic granules with membrane pore forming proteins and enzymes
initiating apoptosis in the target cell.7
11
T-helper cells
T-helper cells (TH cells) are essential for the IS as they can direct the immune response via
interaction with other cells and secretion of cytokines. TH cells express the CD4 co-receptor
and recognize processed antigens associated with MHC class II molecules. When activated in
specific cytokine environments, naive CD4+ T-cells differentiate into different subsets with
distinct effector functions. These specified cells then mobilize and orchestrate other cell
types to effectively clear invading pathogens. Based on their cytokine profile, TH cells can be
subdivided into several TH subsets summarized in Table 2.9
Table 2: Characteristics of TH-cell subtypes10
TH1 differentiation usually occurs in response to intracellular microbes. TH1 mediated
responses include the activation of macrophages and neutrophils and the production of IgG
antibodies by B-cells. IFNγ is the signature cytokine of this subtype. Also the expression of
the transcription factors STAT-4 and T-bet are TH1-associated.11
TH2 cells play a major role in the humoral immune response. Secretion of IL-4, IL-5, IL-9, IL-13
and expression of the transcription factors STAT-6 and GATA-3 are their distinctive feature.
They induce class switching in B-cells through CD40-CD40L interaction and the secretion of
IL-4 and IL-13. An imbalance in favour of a Th2 mediated response is believed to be the
cause of IgE.mediated allergic disorders.12,13
TH9 cells are Foxp3- IL-9+ IL-10+ T-cells that do not suppress T-cell responses even though
they produce IL-10.14 TGF-β induces the differentiation of TH2 cells into TH9 cells.15 This effect
can be potentiated by IL-4 and inhibited by IFNγ.16
12
TH17 cells contribute to the host defense against extracellular bacteria and fungi mainly at
mucosal surfaces.17 Their main transcription factor is RORγt and activation leads to tissue
inflammation18. Approximately 1% of the CD4+ T-cells in peripheral blood are TH17 cells7.
The TH22 subset is characterized by the secretion of IL-22 and TNF-α. These cells don’t
produce IFNγ, IL-4 or IL-1719. Dermal dendritic cells and Langerhans cells can induce the
differentiation of TH cells into this subtype.20 They express proteins involved in skin
remodeling and infiltrate the epidermis of patients with inflammatory skin disorders19.
T-cell cloning
To analyze birch pollen specific T-cells at the single cell level, T-cell clones (TCCs) can be
established from birch pollen-specific T-cell lines by means of limiting dilution. The major
advantage of this method is the ability to:
- identify the protein and epitope specificity of a single cell with proliferation assays
- determine secreted cytokine levels of a single clone
- isolate mRNA to further investigate TCR composition and TF expression
- determine the expression of surface proteins by flow cytometry
13
Birch pollen allergy / Type I hypersensitivity
Allergic diseases have reached epidemic dimensions in urban areas. They are associated with
high economic costs and have a negative effect on the patient’s quality of life.21
Approximately 20% of the population in industrialized countries suffer from immediate
hypersensitivity reactions.22
Pollen from wind-pollinated plants is among the most potent allergen sources. It contains
several proteins which are responsible for cross-reactive allergies to fruits, nuts and
vegetables. Allergen sensitization often occurs via the respiratory mucosa23 and requires
certain concentrations of pollen.24
Genetic predispositions play a critical role in the development of allergies (atopic
predisposition). People with a history of atopy in the family have an increased risk to
develop allergic symptoms.25
Patients suffering from type I allergies have aberrant T-cell responses to harmless antigens,
dominated by TH2 cells. As a result B-cells produce increased amounts of IgE antibodies
against common environmental proteins.
Sensitization phase
An allergic reaction is preceded by a sensitization phase. Atopic individuals react to repeated
exposure to allergens with the activation of specific TH2 cells. APCs take up the allergen and
present it to naive T-cells via their MHC II molecules, directing them towards the TH2
phenotype as shown in Illustration 1. Mouse studies have suggested, that low-dose TLR
Illustration 1: Schematic representation of the sensitization phase1; Adapted from “The future of antigen-specific
immunotherapy of allergy by Valenta R., 2002, Nature Reviews Immunology 2, 446-453;
14
agonists such as LPS can influence dendritic cells in this process.26 TH2 cells secrete cytokines
that lead to the development of characteristic allergic phenotypes such as class switching of
B-cells to IgE (IL-4, IL-13), recruitment of mast cells ( IL-4, IL-9, IL-13) and maturation of
granulocytes (IL-3, IL-4).27 Allergen-specific IgE antibodies bind to high affinity IgE receptors
(FcεRI) on the surface of mast cells, basophilic granulocytes and eosinophilic granulocytes
which are located in several tissues such as the nasal mucosa. FcεRI bound IgE antibodies are
stable for several months to years.
The presence of allergen-specific IgE antibodies must not lead to allergic symptoms but most
sensitized patients react to subsequent exposure of an allergen with immediate clinical
allergic symptoms.
Immediate and late reaction
In the challenge phase or immediate reaction,
mast cell bound IgE antibodies bind to the
allergen as depicted in Illustration 2. Allergens
can have several epitopes or can form
multimers, a process that lead to binding of
neighbouring IgE molecules to the same
allergen. This process called cross-linking leads
to mast cell degranulation and the release of
inflammatory mediators such as histamine and
leukotriens.27 This causes the fast occurring
symptoms 1-30 minutes after allergen contact
which are typical for type I allergies such as
skin hives, allergic rhinitis and conjunctivitis.
The release of chemokines and
proinflammatory cytokines from Th2 cells
recruits macrophages, eosinophiles and
basophiles that release inflammatory mediators
causing a late response 6-27 hours after
allergen contact1(Illustration 3).
Illustration 2: Overview of the immediate reaction1
Adapted from “The future of antigen-specific immunotherapy of allergy by Valenta R., 2002, Nature Reviews Immunology 2, 446-453;
15
Birch pollen allergens
Birch trees are widely spread in Central and Northern Europe and they release large
amounts of pollen during flowering season. The major allergen in the European white birch
(Betula verrucosa) is Bet v 1.28 Individuals who are sensitized to birch pollen are prone to
develop birch pollen-related food allergy due to an IgE- and T-cell-mediated cross-reaction
between Bet v 1 and structurally related food proteins.29,30 It is one of best characterized
allergens identified so far. Birch pollen contains several other proteins that are highly cross
reactive to other allergens found in trees, grasses and weeds such as profilin (Bet v 2), two
calcium binding proteins (Bet v 3 and Bet v 4), an isoflavone reductase homolog (Bet v 6) and
a cyclophilin (Bet v 7). All identified birch pollen allergens are summarized in Table 3.
Illustration 3: Overview of the late reaction occuring 6-27h after allergen contact.1 Adapted from “The future of antigen-
specific immunotherapy of allergy by Valenta R., 2002, Nature Reviews Immunology 2, 446-453;
Table 3: Summary of so far identified birch pollen allergens, amino acids (AA), theoretical isoeletric point (pI), n.a.= no studies available
3-5
16
Figure 1 illustrates the different protein concentrations in an
Austrian birch pollen sample. The identified minor allergens are
indicated by red arrows.
The concentration of specific allergenic proteins in pollen or foods
is thought to have an impact on allergenicity. Nonetheless, the
quantity of allergens in birch pollen has only been estimated for
Bet v 1. It accounts for 10% of the total protein content of B.
Pendula pollen.31 To get an idea of the allergen concentration in
birch pollen, Figure 4 shows SDS-PAGE profiles of different birch
pollen extracts.
Bet v 1 – the major birch pollen allergen
Bet v 1 is the major birch pollen allergen in Europe. Around 60% of birch pollen-allergic
patients react exclusively to this allergen32 and more than 90% of all tree pollen-allergic
patients display IgE antibodies to Bet v 1.3 It is part of the pathogenesis- related proteins (PR
10) family.33 These proteins play a role in the immune system of plants but their
physiological function is still unknown. Allergenic Bet v 1 homologues have been described in
several foods such as hazelnut (Cor a 1)34, peanut (Ara h 1)35, apple (Mal d 1)36, cherry (pru
av 1)37, pear (Pyr c 1), celery (api g 1)38, carrot (Dau c 1)39, soybean (Gly m 4)40 and kiwi (Act d
8)41.
Several isoforms of Bet v 1 are known, differing in their ability to activate T-cells and bind
IgE. Bet v 1.0101 is the most common one. These isoforms can be classified into high,
intermediate and low IgE binding classes shown in Table 4 .42
Figure 1: SDS-PAGE profile of Austrian birch pollen extracts; Adapted from “Proteomic profiling of birch (Betula verrucosa) pollen extracts from different origins by Erler, A. et al., Proteomics 11, 1486-98 (2011). Red arrows indicate the identified minor allergens. Bet v 3 was not included in this study .
2
17
Table 4: (from Ferreira F. et al. 1996): Summary of Bet v 1 isoforms: IgE binding and T-cell reactiviy of the pure recombinant allergens relative to isolated Bet v 1 from birch pollen including all isoforms (natural Bet v 1). T-cell reactivity tested with 48 T-cell clones; IgE binding tested with 30 sera from birch pollen allergic patients.
42
T-cells recognize linear processed amino acid sequences, therefore T-cell epitopes differ
considerably from conformational B-cell epitopes and cross-reactivity with food proteins
cannot be abolished by cooking or digestion. Bet v 1.0101 has been expressed as
recombinant protein and characterized in great detail on molecular and immunological level.
It contains ten prominent T-cell epitopes of which the epitope Bet v 1 142-153 was shown to be
the dominant one.43 Hypoallergenic variants of Bet v 1.0101 have been created reducing the
IgE binding capacities but maintaining the T-cell activating properties.
Minor allergens
Minor allergens are proteins recognized by <50% of sensitized patients.
Bet v 2
Bet v 2 is a 14 kDa protein of the profilin family. These molecules are actin binding proteins
and are found in pollen from trees, weed and grass.44 Approximately 15% of all birch pollen-
allergic individuals are sensitized to Bet v 2.4 Pollen profilins are cross-reacting with profilins
in tomatoes, celery, carrots, peanuts, hazelnuts, bananas, apples and pineapple.45-50
Bet v 3
Bet v 3 is a 23,7 kDa protein that contains three typical calcium-binding motifs. It is
expressed specifically in mature birch pollen and IgE binding requires protein bound Ca2+. 51
The prevalence of recognition has not been determined yet.
18
Bet v 4
Bet v 4 is a 9 kDa protein found in birch pollen with two EF-hand calcium binding motifs.52
Approximately 5% of birch pollen allergic patients and 10-15% of mugwort and timothy
grass- pollen allergic patients have IgE antibodies recognizing Bet v 4.53 It has sequential
homologies to other calcium binding allergens found in Bermuda grass54 and Brassica.55 It
also shares IgE epitopes with Cyn d 7 and Phl p 7, two EF-hand Ca2+ binding allergens found
in grass pollen.56 Most antibodies are directed to the C-terminal EF-hand domain but in
contrast to Bet v 3, IgE recognition doesn’t depend on protein bound calcium as substantial
IgE binding can still be detected after calcium depletion.57
Bet v 6
Bet v 6 is a 35 kDa allergen expressed in birch pollen. It has a high sequence homology with
isoflavone reductase homologue proteins (60-80%) such as the pear allergen Pyr c 5. It was
further shown that Bet v 6 displays reductase activity.58 Mouse antibodies directed against
Bet v 6 recognize cross-reactive proteins in pear and lychee fruit.59 Although only 10% of
birch pollen-allergic subjects are sensitized to Bet v 6, 60 it is thought to represent a highly
cross-reactive allergen in plant foods. The prevalence of recognition has not been
determined yet.
Bet v 7
Bet v 7 is a 18 kDa member of the cyclophilin A family with a cis-trans isomerase activity.61
Cyclophilins have been demonstrated to be stress-induced proteins62 but the physiological
function in pollen is still unknown. Proteins in alder, hazel and oak pollen extracts were
detected by a polyclonal rabbit anti-Bet v 7 antibody, indicating a general immunological
cross-reactivity among plant cyclophilins of group A.63 The prevalence of recognition has not
been determined yet.
To explore the mechanisms that drive Th2 polarization it is important to characterize
involved allergens in great detail. In the present study, I tried to express, purify and
characterize four minor allergens in birch pollen (Bet v 3, Bet v 4, Bet v 6 and Bet v 7). After
purification, their IgE binding capacity, possible oligomerization and, abilitiy to activate
allergen specific T-cells were examined. For further cellular characterization, T-cell clones
and T-cell lines specific for proteins in birch pollen extract were isolated.
19
Aims of the study
The major aims of this project were to
- produce, purify and characterize recombinant Bet v 3, Bet v 4, Bet v 6 and Bet v 7
- isolate and characterize T- cell clones and T-cell lines specific for proteins in birch pollen
extract from birch pollen-allergic patients
20
Materials and Methods
Cloning
Minor Birch pollen allergen DNA sequence
Constructs containing the sequence of minor birch pollen allergens flanked by desired
restriction sites were ordered from a DNA synthesis company (GenScript – Gene synthesis
service). The sequences encoding the minor allergens were obtained codon optimized for
E.coli and cloned in the pUC57 vector.
DNA digestion
For quantitative digestion 1 µg of the DNA sample was incubated with 15 U of the desired
restriction enzymes in the corresponding buffers ( total volume = 50 µl) for 2-3 hours in a
heat block at 37°C.
For test digestions 1 µg of the DNA sample was incubated with 5 U of the desired restriction
enzymes in the corresponding buffers for 1 hour in a heatblock at 37°C.
The digested sample was then separated by agarose gelelectrophoresis.
Dephosphorylation of digested vectors
To prevent religation, digested vectors were dephosphorylized by incubating them with 5 U
of Calf Intestine Alkaline Phosphatase (CIAP 1 U/µl, Fermentas) for 30 min at 37°C in a
heatblock, followed by incubation at 85°C for 15 min to inactivate the enzyme.
Agarose gel electrophoresis
DNA samples were separared by agarose gel electrophoresis containing Ethidium Bromide
(EtBr). For a 1 % (w/v) gel, 1 g of agarose was added to 100 ml 1 x TBE buffer. The solution
was heated in a microwave till the agarose was completely dissolved and the solution was
clear. After cooling to approximately 40 °C two drops of a 0,07% EtBr solution (0.7 mg/mL;
21
AppliChem GmbH, Darmstadt, Germany) were added and the solution was poured in a
BioRad tray for polymerization.
DNA samples were mixed with Fermentas 6x loading dye before loading and the Gene
RulerTM 100 bp DNA ladder marker (Fermentas GmbH) was used as a size marker (100 bp –
2400 bp).
The gels were run at 90 V for ~ 40 min in the BioRad Sub-Cell GT Agarose Gel Electrophoresis
System (Bio-Rad Laboratories Ges.m.b.H.) using 1x TBE as running buffer.
Gel extraction of separated DNA samples using Quia Quick gel extraction kit
The weight of the later used eppendorf tube was measured and the desired DNA band was
cut out of the agarose gel under UV light using a scalpel. The cut out piece was placed in the
eppendorf tube and the weight of the gel piece was determined.
Then the DNA was extracted from the gel using the QIAquick Gel Extraction Kit and following
the manufacturer’s protocol. All centrifugation steps were performed in an Eppendorf 5417C
tabletop centrifuge (Eppendorf AG).
3 x gel volume of QG buffer was added to the gel ( 100 mg = 100 µl)
The sample was heated to 50°C in a heatblock for 10 min and vortexed every 3 minutes
1 x gel volume of Isopropanol was added and the sample was vortexed
The dissolved sample was transfered to a spin column in a 2 mL collector tube and was
centrifuged for 1 min at 13 000 rpm
The flow through was discarded and 500 µl QG buffer were added
The sample was centrifuged for 1 min at 13 000 rpm and the flow through was
discarded
The sample was incubated with 750 µl of PE buffer for 2 minutes at RT and then
centrifuged for 1 min at 13 000 rpm and the flow through discarded
To elute the DNA, the column was placed in a new sterile eppendorf tube and 30 µl of
nuclease free H2O was added directly onto the filter
After 1 min incubation the sample was centrifuged for 1 min at 13 000 rpm
The flowthrough containing the eluted DNA was collected.
The concentration of the DNA was measured via NanoDrop and stored at -20°C
22
DNA Ligation
In order to add a N terminal HIS- tag to the recombinant proteins, all minor allergen genes
were were cloned in the pHIS parallel 2 vector using restriction enzymes and T4 DNA ligase.
To calculate the needed amount of insert, the following formula was used:
ng insert = ng vector (~150 ng) x 10 x (bp insert / bp vector)
The digested DNA fragments were incubated with 2,5 units of T4 DNA ligase (Fermentas,
5U/µl) and the corresponding 10x T4 DNA ligase buffer and nuclease free H2O in a total
volume of 20 µl for 3 hours at RT .
The ligated constructs were then transformed in E.coli Top 10 cells.
Transformation in chemically competent E.coli strains
The constructs were transformed by a heat shock protocol first in E.coli TOP 10 cells (cloning
strain without own plasmids) and then in E.coli BL21(DE3)pLysS cells (expression strain for
quantitative protein expression) (Invitrogen GmbH, Lofer, Austria). All centrifugation steps
were performed in an Eppendorf 5417C tabletop centrifuge (Eppendorf AG).
- 0,3 µg of the vector were added to the thawed E.coli cells and kept on ice for 20 min
- the cells were put into a heatblock at 42°C for exactly 45 seconds and immediately
put back on ice for 2 min
- 1 ml SOC medium was added to recover the cells, thereafter they were kept for 15
min on RT
- Afterwards the cells were put into a heatblock at 37°C for 60 min and 350 rpm (not
really necessary for transformation with a vector)
- 50 µl of the transformed cells were plated on a LB agar plate containing 100 µg/ml
ampicillin to select for cells containing the vector
- The remaining cells were centrifuged in a table top centrifuge for 2 min with 4000
rpm
- The pellet was resuspended in 150 µl supernatant and also plated on a LB-agar plate
with ampicillin
- The plates were incubated over night (o/n) at 37 °C
- On the next day the plates with the grown colonies were stored at 4 °C
- To check the transformed construct, several colonies were picked and seperate
precultures were made in culture tubes containing 5 mL LB-Amp medium.
- The precultures were incubated at 37°C at 220 rpm o/n
- Frozen stocks: On the next day, frozen stocks were prepared by transfering 800µl of
the preculture in a 2 mL cryovial and adding 70 µl of chilled DMSO to the cells
23
- The frozen stocks were immediately stored at -80°C
- Then plasmids were isolated from the precultures and the construct checked by a
test digestion.
- Isolated plasmids containing the correct construct were then transformed by the
described protocol in competent E.coli BL21(DE3)pLysS cells
- One single colony was picked from one plate with a sterile toothpick and put o/n in
5ml liquid LB-amp (100 µg/ml) medium at 37°C in a shaking incubator (~240 rpm) to
grow a preculture for a testexpression and a frozen stock.
Plasmid preparation from E.coli using QUIAprep spin Miniprep Kit
Plasmids were extracted from overnight E.coli cultures using the QUIAprep Miniprep Kit
according to the manufactureres protocol. All centrifugation steps were performed in an
Eppendorf 5417C tabletop centrifuge (Eppendorf AG).
Overnight culture:
Picked colonies were inoculated under sterile conditions in 15 mL culture tubes filled with 5
mL LB-Amp medium. The cultures were incubated at 37°C while shaking at 220 rpm for 16
hours.
Procedure:
- 4 mL of the overnight cultures were spinned down in two sterile 2 mL eppendorf
tubes for 3 minutes at 6800 g
- The Supernatant was discarded and the pellet was dried on paper for 2 min
- The dried pellet was resuspended in 250 µl of cold P1 buffer
- 250 µl of P2 buffer were added and the tube was inverted 4-6 times
- After 4 min 350 µl of N3 were added, the tube was inverted 4-6 times
- The cells were centrifuged for 10 min at 17 900 g at RT
- The supernatant containing the plasmids was poured in the supplied spin column and
centrifuged for 1 min at 17 900 g
- The flow through was discarded
- 500 µl PB were added to the column and it was centrifuged for 1 min at 17 900 g
- The flow through was discarded
- 750 µl PE were added to the column and it was centrifuged for 1 min at 17 900 g
- The column was placed in a new eppendorf tube and 50 µl of Elution buffer (EB) was
applied directly onto the filter
- After 1 minute incubation, the column was centrifuged for 1 min at 17 900g
- The DNA concentration was measured via NanoDrop and the isolated plasmid was
stored at -20°C
24
Protein expression and purification
Testexpression in E.coli BL21
The expression of minor allergens was performed in the E.coli BL21(DE3)pLysS expression
strain (Invitrogen GmbH, Lofer, Austria). This strain encodes a T7 RNA polymerase gene
downstream of a Lac operator. The genes encoding the minor allergens in the transformed
vectors are located downstream of a T7 promoter and lac operator. IPTG was used to induce
the expression of the T7 RNA polymerase which in turn facilitates the expression of the HIS-
tagged minor allergens.
- 1,5 ml of a 5 ml o/n preculture were added to 50 ml pre-warmed LB-amp medium ( --
> 1:30 dilution) and kept at 37°C in a shaking incubator at 220 rpm
- Cells were grown till an OD600 between 0,6- 1
- The optical density was measured in a 1 ml plastic cuvette using a spectral
photometer
- 0h sample: 1 ml of the cell suspension was transformed in an eppi and centrifuged in
a table top centrifuge for 2 min at 3500 g in an Eppendorf 5417C tabletop centrifuge
(Eppendorf AG). Then the pellet was resuspended in 50 µl 1x Sample buffer (SB) and
stored on ice
- IPTG induction: Protein expression was iduced by adding 50 µl of IPTG (1M stock) to
the 50 ml culture (1 mM final IPTG concentration)
- The cells were kept in the shaker at the desired temperature ranging from 18°C to
37°C at 220 rpm
- 1h- 5h samples: Every hour a 50 µl sample was taken from the culture and
centrifuged for 2 min at 3500 g. The resulting pellet was resuspended in 50 µl of 1x
SB and stored on ice. The 0h-5h samples were stored at -20°C.
- Harvesting: After 5h the remaining culture was centrifuged in a Sorvall RC SC PLUS
centrifuge (Thermo Scientific Inc.) for 20 min with 6000 g at 4°C
- The supernatant was discarded and the pellet can be stored at -20°C at this stage
- In order to break up the cells, the pellet was resuspended in 5 mL lysis buffer and
vortexed till the pellet was completely resuspended
- The suspension was poured in a 50 ml falcon tube and a freeze – thaw cycle was
repeated three times using liquid nitrogen (N2) followed by a waterbath at 37°C to
lyze the cells
- If the cell suspension has a gel like structure, incubation with 5 µg/ml DNase at RT
can improve separating the soluble protein fraction from the insoluble
- The lysed cells were centrifuged in a Sorvall RC SC PLUS centrifuge for 30 min at 4°C
with 20000 g
25
- Soluble Protein: The supernatant which was considered to be the soluble protein
fraction was collected in a falcon tube and stored on ice
- Insoluble Protein: Recombinant produced proteins often aggregate in insoluble
inclusion bodies. In order to solubilize these proteins the pellet representing the
insoluble protein fraction was resuspended in Lysis buffer containing 5M Urea.
- The resulting suspension was centrifuged for 30 min at 4°C with 20000 g in a Sorvall
centrifuge
- The supernatant which consists of the insoluble proteins was then collected in a
falcon tube and stored on ice. The remaining pellet was discarded
- Denaturation: to denaturate the samples prior to the SDS PAGE, the 0h-5h samples
were put in a heatblock at 95°C for 15 min. To denaturate the soluble and insoluble
fractions collected after 5 h, 5µl of 4x SB were added to aliquots (15µl) of the
fractions. They were also put on 95°C for 5 min
To determine the optimal expression conditions 12 µl of the collected samples were loaded
on SDS-PAGE gels (15%) .
Separation of protein samples by SDS PAGE
Protein samples were separated by SDS polyacrylamide gelelectrophoresis. They were
denaturated with 2-mercaptoethanol and SDS at 95°C and separated according to their
molecular weight in a polyacrylamide gel by polyacrylamide gelelectrophoresis (PAGE). Gels
containing 13- 17% polyacrylamide were produced (Table 5) and the separated proteins
were visualized by coomassie staining.
Table 5: Separating- and stacking gel solution for 3 gels
26
- The reagents were mixed according to Table 1. The separating gel was poured
between two sealed glas plates.
- 2 cm from the top were left for the stacking gel
- Isobutanol was added on the separation gel to ensure an even surface
- After polymerization of the gel, Isobutanol was removed, the surface was washed
with ddH20 and the stacking gel was poured on top
- After polymerization 5 µl of Fermentas PAGE RulerTM were used as a protein ladder
and 12 µl protein sample was mixed with 4 µl 4 x SB and boiled at 95°C for 15 min
prior to loading.
- Gels were run at 25 - 30 mAmp per gel until the dye front completely left the gel
Coomassie staining
SDS PAGE gels were incubated with the coomassie staining solution (Coomassie brilliant blue
G250) under continuous shaking for ~ 30 min at RT on a slow shaker. The coomassie solution
was discarded and the gels were incubated with a destaining solution containing acetic acid
and methanol, until the background was completely destained and the protein bands were
clearly visible.
Western Blot
Western Blot was used to blot the separated proteins from a SDS PAGE gel onto a Whatman
Protran Nitrocellulose Transfer membrane with 0.2 µm pore size (Whatman GmbH, Dassel,
Germany) using an electric current generated in a Biosciences TE22 Tank Transfer Unit (GE
Europe GmbH, Munich, Germany). Gels were blotted for 1 hour at 150 mA.
Thereafter HIS- tagged proteins were detected by a mouse Penta-HisTM IgG1 antibody
(QUIAGEN)
27
Negative pole
Cassette of blotting chamber
SDS PAGE Gel
Whatman paper
Sponge
Nitrocellulose membrane
Whatman paper
Sponge
Cassette of blotting chamber
Positive pole
Scheme of the assembled blotting chamber:
All components were equilibrated in transfer buffer
- The membrane was dryed on paper and the bands of the protein marker were
marked
- The dryed membrane can be stored at -20°C at this point
- The membrane was incubated with 20 mL Blocking buffer at RT on a shaker for 2h to
block unspecific binding of antibodies
- Afterwards the membrane was washed for 3x with 15 mL Wash buffer for 10 min at
RT
- Then it was incubated for 2h at RT with a mouse Penta-HisTM IgG1 antibody
(QUIAGEN) diluted 1:4000 in TBS/0.1% (v/v) Tween 20 supplemented with BSA (4%
w/v) (this step can also be performed o/n at 4°C)
- Then the membrane was washed for 3x with ~15 mL Wash buffer for 10 min at RT
- Incubated for 1.5h at RT with a HRP- tagged Goat anti Mouse IgG antibody (Cell
- Signaling Technology Inc, Danvers, USA) diluted 1: 10 000 with blocking buffer
- Washed 3x with ~15 mL Wash buffer for 10 min at RT
- Then the membrane was dried and placed in a clean petri dish
- A chemiluminescent reagent was used to detect the HRP linked sec. antibodies
(LumigenTM PS-3 detection reagent, GE Healthcare UK Ltd, Birminghamshire, UK)
- The cleavage of the chemiluminescent agent by the HRP creates an emmission of
light which darkens the photofilm
28
- 4 mL Lumigen solution A were mixed with 100 µL detection reagent and the
membrane was incubated for 5 min in the dark
- The membrane was fixed in a Hyperfilm detection box
- A photographic film (Amersham HyperfilmTM MP ; GE Europe GMbH, Munich,
Germany) was exposed to the membrane in a darkroom and developed afterwards in
a AGFA CP1000 developing unit (Agfa Graphics Germany GmbH & Co, KG, Düsseldorf,
Germany)
Expression of recombinant birch pollen allergens
In order to produce minor allergens in lager quantities, the proteins were expressed in 2 L
E.coli BL21(DE3)pLysS cultures. Optimal temperature and duration of the expression were
determined by testexpressions. The cells were broken up with lysis buffer and freeze-thaw
cycles. Most of the proteins were purified from the soluble fraction to maintain the natural
conformation of the protein. All centrifugation steps were performed in a SORVALL RC SC
PLUS centrufuge (Thermo Scientific Inc., Rockford, USA)
- o/n culture: Cells from a E.coli BL21 (DE3) frozen stock, containing a pHIS parallel 2-
minor allergen construct were inoculated in 70 mL of prewarmed LB- amp medium
- the cells were incubated at 37°C in a shaker o/n
- on the next day 66 mL of the preculture were added to 2 L prewarmed LB- amp
medium (2x 33 ml preculture in 1 L of LB Medium in a 5 L Erlenmeyer flask)
- the culture was grown at 37°C in a shaker till an OD600 of 1,1
- the expression of the minor allergen was induced by addition of IPTG (final
concentration: 0,4 mM)
- after 4 ½ h of expression at 37°C the cells were harvested by centrifugation at 4000 g
for 30 min at 4°C and the cell pellets were stored o/n at -20°C
- To lyse the cells, the pellet was resuspended in lysis buffer (1/10 of the former
volume -> 200 ml) and vortexed till the pellet was completely resuspended
- The suspension was poured in several 50 ml falcon tubes and shock frozen in liquid N
followed by thawing in a 37°C waterbath. This freeze-thawing cycle was repeated 2
times
- The cell suspension was incubated with DNase (5 µg/ml) at RT on a rock n roller to
improve separation of the soluble and insoluble fractions
- The cell lysate was poured in centrifugation tubes and centrifuged for 30 min at 4°C
with 18000 g
- The supernatant was collected, filtered through a MILLEX GV low protein filter unit
(0.22 µm; Millipore Corporation) and stored at 4°C
29
Purification of His tagged proteins by Ni affinity chromatography
His-tagged minor allergens were purified using His-Trap FF crude 1 mL columns (GE Europe
GmbH, Munich, Germany). The His-tag on the N treminus of the minor allergen binds to the
immobilised nickel and any untagged proteins pass through the column. Bound proteins are
eluted by an increasing imidazol gradient that competes with the His tag for the Ni agarose.
The purification of the proteins was performed using the ÄKTATM prime protein purification
system (GE Europe GmbH, Munich, Germany) according to the manufacturer’s instructions.
- The His-Trap FF crude 1 mL column (GE Europe GmbH, Munich, Germany) was
washed with 10 mL (10 x column volume) of ddH2O at a low flow rate ( ~ 1 ml/min)
and equilibrated with 10 column volumes of Lysis buffer
- The ÄKTAprime system was washed with 40 mL of ddH2O and 40 mL of Elution
buffer, then equilibrated with 40mL of Lysis buffer buffer
- The filtered supernatant was loaded onto the column at a low flow rate (1-2 mL /min)
with a backpressure maximum of 0.3 MPa
- the flow through was collected and stored on ice (flow through fraction)
- The column was washed with 10 column volumes of start buffer and the flow
through was also collected as the WASH fraction
- Then the protein was eluted with 30 mL of an increasing imidazol gradient (100%
Lysis buffer/ 0% Elution buffer 20% Lysis buffer/ 80% Elution buffer) and fractions
of 1mL were collected and stored on ice
- The ÄKTAprime system was washed with 40 mL of ddH2O and 40 mL of 20% EtOH
- The His-Trap FF crude column was washed with 10 mL of ddH2O and 10 mL of
100% EtOH and the stored at 4°C
Prior to dialysis, the eluted fractions were collected and analysed by means of SDS PAGE
followed by coomassie staining.
30
Preparation of the dialysis membrane
The dialysis membrane (4 m length; Spectra/Por, Spectrum Medical Industries Inc.) was
incubated for 2 hours at 60°C in 2000 mL pre-warmed dialysis preparation buffer. From time
to time the solution was stirred. This step was repeated once. Afterwards, the membrane
was incubated at 60°C in 2000 mL pre- warmed ddH2O. This step was repeated till the
solution was clear. The solution was slowly cooled down to 4°C. The dialysis membrane was
stored in ddH2O supplied with 1 mL/L chloroform at 4°C.
Dialysis of eluted fractions
Eluted fractions containing protein were pooled and dialysed against either PBS or a Sodium
phosphate buffer to remove toxic imidazol and to minimize protein precipitation. Optimal
buffer and pH of the dialysis buffer were determined empirically.
Pooled fractions were
transfered in a
semipermeable dialysis
tube (cut off at 5 -7 kD,
Spectra/Por, Spectrum
Medical Industries Inc) and
dialysed against 2 L dialysis
buffer, at 4°C under stiring
(schematically depicted in
Figure 2). The dialysis
buffer was changed 4x (1x
in the morning, 1x in the
evening for 2 days). 100
mM Sodium phosphate
buffer with a pH of 6
turned out to be optimal
for most of the minor
allergens.
Figure 2: Scheme of the dialysis of Bet v 6 against PBS.
31
Endotoxin removal
To reduce LPS mediated side effects, such as activation of the TLR4 pathway in cellculture
experiments, endotoxin was removed from the dialysed samples using EndoTrap® red 1 mL
columns (Hyglos GmbH, Germany) according to the manufacturer’s protocoll. These columns
contain a resin that specifically binds LPS and lets the aquarious sample pass through.
- The protein sample was diluted 1:2 with endotoxin free water
to decrease the salt concentration which could reduce the
efficiency of the column
- All used equilibration and regeneration buffers (EB, RB) were
filtered and degassed using a Steriltop-GP Filter Unit (0,22 µm,
Millipore Corporation) connected to a vacuum pump
- All samples and buffers were kept on ice to avoid degradation
of the protein
- The column was first regenerated and then equilibrated with
6 mL of regeneration/equilibration buffers
- The sample was applied and the flow through was collected
- 100 µl of the original sample were retained to determine
endotoxin removal efficiency and protein loss during removal
- The column was filled with 1 mL of EB to collect the sample
left in the column
- At the end the column was equilibrated with 6 mL EB
- To achieve a highly sufficient endotoxin reduction in the
sample, the removal was repeated two times using the same
column
- The collected samples were filtered through a MILLEX GV low
protein filter unit (0,22 µm, Millipore Corporation, Billerica,
USA) under sterile conditions and stored at 4°C.
- The column was filled with 1 ml RB 0,02% sodium azide, stored at 4°C and can be
reused with the same protein
32
Bicinchoninic acid (BCA) assay
Protein concentrations were determined using the Pierce Endogen BCA (Thermo Scientific
Inc., Rockford, USA) assay according to the manufacturer’s protocol. Peptide bonds in the
sample reduce Cu2+ ions of the copper sulfate in the reagents, to Cu1+ ions. Two
Bicinchoninic acid molecules chelate with each reduced Cu1+ ion, forming a purple colored
product that strongly absorbs at 562 nm. The concentration of the protein can be
determined by comparing the absorption of the sample to a BSA standard row.
- Standard 96well plates were used for this assay
- BSA standard row:
- 2000 µg/mL
- 1500 µg/mL
- 1000 µg/mL
- 750 µg/mL
- 500 µg/mL
- 250 µg/mL
- 125 µg/mL
- 25 µg/mL
- 0 µg/mL
- 25 µl of the standard row and the protein sample in different dilutions were added to
the plate (dilutions were made with ddH2O)
- The detection reagents were mixed in a 1 : 50 ration (Sol A : Sol B)
- 200 µl of the detection reagent were added (containing copper sulfate and
bicinchoninic acid) to each well
- The plate was mixed gently and incubated for 30 min at 37°C
- The plate was cooled to RT
- The absorption at 562 nm was measured using a Spectra max Plus 384 plate reader
(Molecular Devices, Sunnyvale, USA)
33
Determine endotoxin levels (LAL assay)
To determine the remaining endotoxin concentration in the sample, a chromogenic LAL
assay was performed. Bacterial endotoxins (especially LPS) catalyze the activation of an
enzyme in the Limulus Amebocyte Lysate which in turn releases p-nitroaniline (pNA) from a
synthetic substrate, producing a yellow color. The pNA release is measured photometrically
at 405-410 nm. The concentration of endotoxins can be calculated using an endotoxin
standard.
- The vial with lyophilized E.coli endotoxin stock (20 EU/mL) was filled with 1 mL
endotoxin free H2O (= LAL water) and vortexed for 15 min
- The vial with the substrate was filled with 6,5 mL endotoxin free water and put in a
37°C waterbath 5 min before use
- A flat bottom 96 well plate (Corning Inc., Netherlands) was used for the assay
- Two standard rows were prepared seperately in endotoxin free 25 mL sterilin tubes
- 1 EU/mL = 100 µl endotoxin stock + 1900 µl LAL water
- 0,5 EU/mL = 500 µl 1 EU/mL + 500 µl LAL water
- 0,25 EU/mL = 500 µl 1 EU/mL + 1500 µl LAL water
- 0,1 EU/mL = 100 µl 1 EU/mL + 900 µl LAL water
- Several dilutions of the protein samples were prepared, depending on the expected
endotoxin concentrations:
- Without LPS removal = 1:100, 1:10 000
- After 1x LPS removal = 1:100, 1:10 000
- After 2x LPS removal = 1:100, 1:10 000
- After 3x LPS removal = pure, 1:100, 1:1000
- The 96 well plate was heated to 37°C on a heatblock
- 50 µl of the prepared standard rows and samples were added to the wells
- 3 mL of LAL water were added to the vial containing the Amebocyte Lysate
- 50 µl of the lysate were added to the wells followed by gentle mixing, incubation
time exactly (!) 10 min (start counting after adding lysate to the first well)
- After 10 min 100 µl of substrate were added in each well, followed by gentle mixing,
incubation for exactly 6 min on the heatblock
- After 6 min 50 µl of the STOP reagent were added in each well
- The pNA release was measured photometrically at 405-410 nm using a Spectra max
Plus 384 plate reader (Molecular Devices, Sunnyvale, USA)
34
Confirmation of IgE binding (ELISA)
The conservation of IgE epitopes on recombinant proteins was determined by IgE ELISA.
Different allergens were coated on Nunc Maxisorb 96 well plates (Thermo Scientific Inc.,
Rockford, USA), followed by blocking with HSA and incubation with sera from birch pollen
allergic patients. Specific IgE antibodies bind to the recombinant proteins and are detected
by a secondary antibody coupled with an alkaline phosphatase.
Sera from several birch pollen allergic patients were selected with significant IgE binding to
proteins with the same molecular weight as the produced allergens in an IgE immunoblot
with birch pollen extract. (Bet v 3 = 23 kDa, Bet v 4 = 9 kDa, Bet v 6 = 33 kDa, Bet v 7 = 18
kDa)
Sera from non-allergic and a Bet v 1-allergic patients served as negative and positive control,
respectively.
- A Nunc Maxisorb 96 well plate (Thermo Scientific Inc., Rockford, USA) was coated
with different proteins
- Coating: The proteins were diluted in carbonate buffer (pH=9,6) and 50 µl were
added to each well
- The plate was stored over night at 4°C
- The coating solution was removed and the plate was washed twice with PBS 0,05%
Tween (200 µl/well). The solutions were removed by flicking the plate over a sink and
patting the plate on a paper towel
- Blocking: To block the remaining protein binding sites the coated wells were
incubated with 100 µl of PBS 0,05%Tween 1%HSA for 5h at room temperature
- Incubation with Antibody: The sera/plasma were diluted with PBS 0,05 % Tween 1 %
HSA and 50 µl/well were added to the plates.
- The plates were incubated over night at 4°C
- Detection: The wells were washed 5 times with 200 µl of PBS 0,05 % Tween
- 50 µl of a Mouse anti-human IgE antibody coupled with an alkaline phosphatase (AP)
(Diluted 1:3000 with PBS 0,05%Tween 1%HSA) were added to each well
- Incubated for 1h at 37°C then for 1h at 4°C
- The wells were washed for 5 times with 200µl of PBS 0,05%Tween
- Incubated with 100 µl of Paranitrophenylphosphate (1 mg/mL) per well at 37°C
- The absorption was measured photometrically at 405/550 nm using a Spectra max
Plus 384 plate reader (Molecular Devices, Sunnyvale, USA) after several timepoints
( 2h, 3,5h, 5h and 19h)
35
Tissue culture
Patients with birch pollen allergy
All birch pollen allergic patients included in this study had rhinoconjunctivitis in spring and
positive skin prick reactions (wheal diameter > 5mm) to birch pollen. All patients gave
written consent before enrolement in the study which was approved by the local Medical
Ethical Committee of Vienna.
PBMC isolation by Ficoll gradient
Peripheral blood mononuclear cells (PBMCs) were isolated from heparinized blood of birch
pollen allergic patients by ficoll gradient centrifugation. All centrifugation steps were
performed in an AllegraTM X-12R centrifuge (Beckman Coulter)
- Blood was collected in heparin tubes (9 mL LH Lithium Heparine, Vacuette) or a Blood
Bag and poured in a sterile 1 L glass bottle
- The heparin tubes were washed 2 x with DPBS (Gibco®, Invitrogen GmbH, Austria)
and DPBS was added to the heparinized blood till a 1:2 dilution was reached
- 50 mL Falcon tubes were filled with 15 mL Ficoll solution
- 35 mL diluted blood was gently pipetted on the top of the Ficoll solution
- The tubes were spinned 30 min at 400 g at RT without brake
- The plasma was collected in a new falcon tube, around 10 mL of plasma were left in
the tube
- The white blood cell ring fraction of two gradients were combined in a new 50 mL
Falcon tube using a sterile 5 mL glass pipette (aspiration of ficoll was avoided)
- The volume of the tubes was adjusted to 50 mL using DPBS
- The tubes were spinned for 10 min at 300 g at RT
- The supernatant was discarded and the pellet was loosened by tapping on the flask
- The pellets were resuspended in 5 mL DPBS and the cells from two tubes were
combined in one. The empty tubes were rinsed with DPBS and added to the
combined cell suspensions.The volume of the tubes was adjusted to 50 mL using
DPBS
- The tubes were spinned for 8 min at 275 g at RT, the pellets resuspended in DPBS and
the cells from all tubes combined in one
- The volume of the cell suspension was adjusted to 50 mL with DPBS and the cells
were counted with a Bürker- Türk counting chamber (0,1 mm depth, BRAND,
Germany)
36
Stimulation of PBMCs (Primary response)
To test a possible toxicity of recombinant allergens and to define their optimal concentration
in T-cell proliferation assays primary responses were performed.
Isolated PBMCs were distributed in a 96 well round bottom culture plate (TC Microwell 96U,
NUNCTM, Denmark) (200 000 cells/well) and stimulated with titrated allergens, a medium
control and a positive control using 2 Units of IL-2 per well. All stimulations were performed
in triplicates and the allergens were diluted in AIM V (Gibco®, Invitrogen GmbH, Austria) to
the desired concentration to minimize stimulation by the culture medium.
The cells were incubated for 6 days, then 3H labeled thymidine (Perkin Elmer, 1 µCi/mL) was
added to the PBMCs (final concentration 0,5 µCi/well). After 12-16h the cells were harvested
on a fibreglas filter (Printer Filtermat A 90 x 120 mm, Perkin Elmer), 4-5 mL of szintilization
liquid (Betaplate Scint, Perkin Elmer) were added and the converted radiation measured by a
ß-counter (MicroBeta TriLux, Perkin Elmer)
Generation of T-cell lines
Addition of the allergen led to the enrichment of allergen specific T-cells and to the
upregulation of the IL-2 receptor. Addition of IL-2 at day 4-6 led to increased survival and
proliferation of T-cells. At day 8-12 blast enrichment was performed to remove all dead cells.
All centrifugation steps were performed in an AllegraTM X-12R centrifuge (Beckman Coulter)
Preparation of T-cell line (Day 0)
PBMCs isolated from birch pollen allergic patients were diluted in AIM V (Gibco®, Invitrogen
GmbH, Austria) and added to a 24 well cell culture plate (Corning Inc., Netherlands) (1.5 Mio
PBMCs/ well). Tested allergens/proteins were diluted to the desired concentration in UCØ,
one well with PBMCs only treated with UCØ as a control.
Addition of IL-2 (Day 4-6)
Between day 4 and 6, T-cell clusters were visible under the microscope. IL-2 was diluted in
UCØ and added to the wells drop by drop (10 U IL-2 in 500 µl UCØ/ well) . After addition of
IL-2 the cells were checked every day under the microscope. From day 8 on blastenrichment
could be performed.
Blast enrichment (Day 8-12)
The stimulated PBMCs were resuspended and transfered from the 24 well plate to 25 mL
sterilin tubes. Touching the bottom of the well was avoided while resuspending to prevent
detachment of unwanted fibroblasts. The wells were washed 2 x with 1 mL UCØ and the cells
37
were then transfered in the 25 mL sterilin tubes. 7 mL ficoll solution was overlayed with the
resuspended cells and the dead cells were separated by density gradient centrifugation at
390 g for 15 min without brake. The cells from the interphase (yellow ring visible above the
ficoll) were transfered in a new sterilin tube together with 10 mL UCØ. The cells were
centrifuged at 800 g for 10 min, the suppernatant aspirated and the pellet resuspended in
1 mL UCØ. The cells were counted with a Bürker- Türk counting chamber (0,1 mm depth,
BRAND, Germany) with trypan blue and diluted to 50 000 cells/mL. 500 cells were used for
T-cell cloning and the remaining cells were pooled to establish a T-cell line.
T-cell line
The remaining T-cells from the blast enrichment were pooled and transfered to a sterile 96
well round bottom culture plate (TC Microwell 96U, NUNCTM, Denmark). 200 000 T-cells in
100µl UC+HUS were incubated together with 100 000 irradiated PBMCs (= Feeder cells) in
100µl UC+HUS and 2 U of IL-2 in a well.
The T-cell lines were expanded 2 x a week with 100 000 unspecific irradiated feeder cells and
2 U IL-2 per well. They were rested for 10 days prior to specific stimulation with allergens.
Specific stimulation of T-cell lines
To determine the specificity of birch pollen specific T-cell lines to different allergens
secondary responses were performed.
The specific stimulations were performed in sterile 96 well round bottom culture plate (TC
Microwell 96U, NUNCTM, Denmark)
The expanded T-cell lines were stimulated with birch pollen extract (25 µg/mL), recombinant
birch pollen allergens (5 µg/mL), and Bet v 1 a homologous proteins in peach and apple
(5 µg/mL) in the presence of 200 000 irradiated, autologous PBMCs per well. IL-2 (2 U/well)
and PHA (0,5%) treated cells served as positive control.
All stimulations were performed in duplicates and compared to untreated T-cells incubated
with autologous PBMCs. The proliferation was assesed after 48h by 3H-thymidine
incorporation (0,5 µCi/well).
A mean SI of >2 was defined as specific T-cell proliferation.
38
Epitope mapping of Bet v 1-specific TCCs
To determine the epitopes of Bet v 1a that are recognized by T-cells, an epitope mapping
was performed.
The assays were performed in sterile 96 well round bottom culture plate (TC Microwell 96U,
NUNCTM, Denmark).
Rested birch pollen-specific T-cell lines and clones were stimulated with a pannel of 50
overlapping, synthetic 12-mer peptides (5 µg/mL) (Mimotopes, Biotrend), representing the
complete amino acid sequence of Bet v 1a43. The T-cell cultures were incubated with the
peptides in the presence of irradiated, autologous PBMCs (100 000 cells/well).
The proliferation was assessed after 48h by 3H-thymidine incorporation. A mean SI of >2 was
defined as specific T-cell proliferation after incubation with the peptides.
Cloning by limiting dilution
Birch pollen specific T-cell clones (TCC) were established from birch pollen specific T-cell
lines by means of limiting dilution and tested for their reactivity with birch pollen extract and
recombinant allergens. Specific TCCs were characterized by flow cytometry and checked for
allergen induced proliferation and cytokine production.
T-cells collected after blast enrichment were diluted in two 1:10 dilution steps with UCØ to
500 cells /5 mL. These 500 cells were incubated in a sterile 200 mL glass bottle with 175 mL
UC+HUS, 300 Mio irradiated PBMCs (=Feeder cells) resuspended in 20 mL UC+HUS and 4000
U IL-2. As last step 0,5 mL PHA (100%) were added and the suspension distributed among 10
sterile 96 well round bottom cell culture plates (200 µl/well). The cells were incubated for 14
days at 37°C 5% CO2 95% rH.
1st screening: After 14 days the cells were analysed under the microscope: (2nd screening
after 21 days 3rd screening after 28 days)
- Wells containing a clone that has not proliferated enough were labeled with a dot on the
lid of the plate: 100µl of the supernatant were aspirated and 100 000 feeder + 2 U IL-2
were added to stimulate proliferation
- Wells containing a clone that had proliferated enough to be split 1:2, were labeled with
a circle on the lid
39
- Clones labeled with a circle were transfered to a new sterile 96 well round bottom
culture plate and split 1:2 (--> 2 wells per clone). These clones were numbered
consecutively and rested for 10 days
- After 10 days, one well per expanded clone was used for specific stimulation.
Birch pollen-reactive TCCs were expanded by alternating turns of stimulation with irradiated
PBMCs together with allergen or IL-2.
Specific stimulation of T-cell clones
80% of the medium from one well of each clone was aspirated and 200 µL UCØ were added.
The cells were resuspended gently, transfered on a new sterile 96 well round bottom culture
plate and divided among two wells. One well of each clone recieved 100 000 autologous
PBMCs in UCØ = unstimulated. The cells in the other well were incubated with 100 000
autologous feeder in UCØ together with recombinant allergen = stimulated. The optimal
allergen concentration was determined empirically. After 48h 100 µl of the supernatant was
collected to determine the amount of produced cytokines and cell proliferation was assesed
by 3H Thymidine incorporation. Incubated clones with a SI (= stimulation index = stimulated/
unstimulated well) >5 were counted as allergen specific.
Cytokine measurement
Supernatants were collected 24h and 48h after stimulation. Cultures containing TCCs and
PBMCs alone served as controls. Cytokine levels in supernatants were measured using the
Luminex system. TCCs were assigned to Th subsets according to the released IL-4 and IFNγ
levels:
Th2 = IL-4 : IFNγ greater than 5
Th1 = IL-4 : IFNγ less than 0,2
Th0 = IL-4 : IFNγ 0.2 to 5
40
Characterization of TCCs by flow cytometry
To further characterize the allergen specific TCCs they were rested for 7 days and stained
with:
Antibody Isotype Dilution Company
TCRα/β - FITC mIgG1 1:10 BD
TIM 3 - PE mIgG1 1:10 BioLegend
CD4 - PerCP mIgG1 1:20 BD
CCR3 - APC mIgG2b 1:20 BioLegend
CLA - FITC rIgM 1:10 Pharmingen
CCR6 - PE mIgG1 1:10 BD
CD 161 - APC mIgG1 1:5 BD
CCR5 - FITC rIgG2a 1:10 BioLegend
CRTh2
unlabeled rIgG2a 1:20 Pharmingen
Goat anti rat
IgG - PE
1:1000 BD
Isotype matched antibodies were used as controls. In pilot experiments some TCCs were
stained 24h (activated) and 7 days (rested) after allergen stimulation. A downregulation of
CD3 and Cr Th2 in the activated cells was observed. Therefore all TCCs were stained 7 days
after allergen specific stimulation.
Harvesting cells: Allergen specific T-cells were pooled in micronic tubes together with 1 mL
FACS buffer. The cells were centrifuged for 8 min at 700 rpm in a AllegraTM X-12R centrifuge
(Beckman Coulter) and the supernatant aspirated. Blocking: The cell pellet was resuspended
in 50 µl blocking buffer (AB serum (20%) in FACS buffer) and incubated for 30 min at 4°C.
Staining: The cells were centrifuged for 8 min at 700 g in a AllegraTM X-12R centrifuge
41
(Beckman Coulter) and the supernatant aspirated. Then the cells were incubated with 30 µl
of prepared antibody solutions after one washing step and incubated for 30 min at 4°C.
Thereafter the cells were centrifuged, the supernatant aspirated, the cells resuspended in
500 µl FACS buffer and transfered in FACS tubes for analysis.
Analysis was performed on a FACStar plus (Beckton Dickinson, San Jose) with CELLquest
Software version 3.3.
mRNA isolation using RNeasy kit (Quiagen)
To characterize the T-cell receptor, mRNA was islolated from allergen specific TCCs with the
RNeasy mRNA isolation kit (QUIAGEN) by following the manufacturer’s protocol. All
centrifugation steps were performed in an Eppendorf 5417C tabletop centrifuge (Eppendorf
AG).
12 wells of each allergen specific TCC were reserved for mRNA isolation and expanded three
times without the addition of irradiated PBMCs to avoid contamination with feeder mRNA.
The cells were rested for 7 days and collected in a 25 mL sterilin tube. The cells were lysed by
resuspending them in 600 µl RTL buffer (+ ß mercaptoethanol). The lysate was homogenized
by passing it 5 x through a blunt 20-gauge needle. One volume of 70% EtOH was added and
700 µl of the sample loaded onto a RNeasy column in a collection tube. The column was
centrifuged for 15 sec at 8000 g and the flow through discarded. This was repeated till the
full lysate was loaded onto the column. Then 700 µl RW1 buffer were added to the column,
it was centrifuged for 15 sec at 8000 g and the flow through was discarded. 500 µl RPE buffer
were added to the column and it was centrifuged for 15 sec at 8000 g. Then 500 µl RPE
buffer were loaded to the column and it was centrufuged for 2 min at 14 000 g. To elute the
mRNA, the column was placed into a 1.5 mL collection tube and 30 µl nuclease free water
(QUIAGEN) were added directly onto the membrane of the column. It was centrifuged for 1
min at 8000 g and put on ice. The concentration of the eluted mRNA was measured via
NanoDropTM 1000 (PEQLAB, Germany) and then either direclty transcribed to cDNA or stored
at -80°C.
42
Transcription to cDNA using the GeneAmp RNA PCR kit
The isolated mRNA from the allergen specific TCCs was transcribed to cDNA by PCR using the
GeneAmp RNA PCR kit (Applied Biosystems, USA).
The following master mix was prepared on ice:
Master mix 1 tube (volume: 40 µl)
10 x PCR buffer II 4 µl
MgCl (25 mM) 8 µl
dATP, dCTP, dGTP, dTTP (10 mM) 4 µl per base
Oligo d(T)16 primer (50 µM) 2 µl
RNase inhibitor (20 U/µl) 2 µl
MuLV Reverse Transcriptase (50 U/µl) 2 µl
isolated RNA 6 µl
The PCR was performed using a peqSTAR 96 HPL Gradient thermocycler (PEQLAB, Germany)
with the following settings:
Heat Lid to 110°C
Pause at 20°C
42°C for 1 hour
95°C for 5 min
Store forever at 4°C
After transcription the cDNA was stored at -20°C.
43
T-cell receptor family typing
The T-cell receptor family type of the α and β chain was determined by PCR to further
characterize the TCR and to confirm the monoclonality of TCCs.
In this assay the isolated and transcribed cDNA of the T-cell clones was used as a template
together with a constant reverse primer and family type specific forward primers in a PCR.
Primer amplifying a housekeeping gene (ß-actin) were used as a positive control and
reaction mixes without template served as negative controls.
The following components were mixed on ice:
Master mix 1 tube (volume: 20 µl)
Nuclease free water (QUIAGEN) 14.3 µl
10 x PCR buffer (Dynazyme) 2 µl
dNTPs (10 mM) 0.5 µl
DyNAzymeTM II DNA polymerase (2 U/µl) 0.2 µl
α/β/ßactin 3’ and 5’ primer (5 mM) 1 µl each
Template cDNA (diluted 1:5) 1 µl
44
The PCR was performed using a peqSTAR 96 HPL Gradient thermocycler (PEQLAB, Germany)
with the following settings:
Heat Lid to 110°C
95°C for 1 min
Pause at 95°C put in PCR tubes
94°C for 3 min
Start loop (35x)
95°C for 30 sec
57°C for 35 sec
72°C for 45 sec
Close loop
72°C for 7 min
Store forever at 4°C
Afterwards the samples were mixed with Fermentas 6 x loading dye and analysed on a 1%
(w/v) agarose gel.
Storage of T-cell clones
Remaining allergen specific T-cell clones were stored in liquid N2.
TCC freezing medium was prepared (90% FCS, 10% DMSO, Gentamycin (2 mL/L)) and stored
on ice. 2 mL cryovials were labeled and also stored on ice. Depending on their density 8-12
wells of TCCs were pooled in a 25 mL sterilin tube and centrifuged at 700 g for 8 min in a
AllegraTM X-12R centrifuge (Beckman Coulter). The supernatant was aspirated and the cells
resuspended in chilled freezing medium. 1 mL of the cell suspension was transfered in each
cryovial and stored o/n in a cryocontainer at -80°C. The next day they were stored in a liquid
nitrogen dewar.
45
Results
Production and purification of birch pollen allergens
Cloning of DNA encoding birch pollen allergens in the pHIS parallel 2 vector
DNA sequences encoding the genes of the allergens Bet v 3 and Bet v 7, flanked by
restriction sites for BamHI and Not I were ordered from a DNA synthesis company (GenScript
– Gene synthesis service). For protein expression, the synthesized DNA sequences were
fused with a N terminal HIS- tag by cloning it in the pHIS parallel 2 vector (sequence in the
appendix) using the BamHI and Not I restriction sites.
Sequence of Bet v 3:
>gi|488604:1-618 B.verrucosa Betv III mRNA for pollen allergen
TATAGGATCCATGCCCTGTTCCACAGAAGCCATGGAAAAAGCAGGGCATGGGCATGCAAGTACACCTCGCAAGCGTAGCCTCAGCAACTCGTCCTTCCGCCTCCGCTCAGAGAGTCTGAATACCCTCCGCCTCCGACGCATATTCGATCTATTTGACAAGAACAGCGATGGCATCATCACCGTCGATGAACTCAGCCGAGCCCTCAACCTTCTTGGCCTCGAAACCGACCTCTCGGAGCTCGAATCCACCGTCAAATCATTCACTCGAGAGGGCAACATTGGGCTTCAATTCGAAGACTTCATATCGCTGCACCAATCCCTAAACGACAGCTACTTTGCTTACGGCGGCGAGGATGAGGATGATAATGAGGAGGATATGAGAAAGAGCATATTGTCGCAAGAGGAAGCAGATTCTTTCGGAGGCTTCAAGGTGTTCGACGAGGACGGGGATGGTTACATATCGGCCAGAGAACTGCAAATGGTACTGGGGAAGCTGGGATTCTCTGAAGGGAGCGAGATTGACAGAGTTGAGAAGATGATCGTGTCCGTTGACAGCAACCGAGATGGCCGGGTTGATTTCTTTGAGTTCAAGGATATGATGCGTAGCGTTCTCGTGCGGAGCTCTTGAGCGGCCGCTATA
Sequence of Bet v 7:
>gi|21886602:35-556 Betula verrucosa mRNA for peptidylprolyl isomerase (cyclophilin), ppiase gene (CyP)
TATAGGATCCATGGCGTCAAACCCTAAGGTCTTCTTCGACATGGAGGTCGGTGGCCAGCCCGTTGGGCGGATGTGATGGAGCTCTACGCCGACACCACTCCCCGCACGGCCGAGAACTTCCGGGCCCTCTGCACCGGTGAGAAGGGCAACGGCCGCTCCGGCAAGCCCCTCCACTACAAGAAATCGTCCTTCCACAGGGTGATCCCCGGGTTCATGTGCCAGGGGGGCGACTTCACTGCCGGAAACGGCACCGGTGGCGAGTCCATCTACGGCGCCAAGTTCGCCGATGAGAACTTCATCAAGAAGCACACCGGCCCCGGCATCCTCTCCATGGCTAATGCCGGCCCCGGCACCAATGGATCTCAGTTCTTCATCTGTACCGCCAAGACCGAGTGGCTCGACGGCAAGCACGTGGTGTTCGGCCAGGTCGTGGAGGGTCTGGACATCGTGAAAGCCATCGAGAAGGTCGGGTCCAGCTCCGGCAGGACTTCCAAGCCCGTGGTCGTCGCCGACTGTGGTCAACTCTCTTAGGCGGCCGCTATA
Restriction sites for BamHI and Not I in red
46
The constructs were transformed into One Shot®TOP10 Chemically competent E.coli cells
(Invitrogen) by a heat shock protocol and plated on LB-agar plates containing ampicillin as a
selection marker. Several colonies were picked and the plasmids isolated from 5 mL cultures
using the QUIAprep spin Miniprep Kit (QUIAGEN). The correct size of the insert was checked
by testdigestion and agarose gel electrophoresis (Figure 3).
Figure 3: Test digestion of Bet v 3 and Bet v 7 constructs: Digested constructs were separated on a 1%(w/v) agarose gel
containing EtBr. M: gene ruler 100 bp ladder marker; Bet v 4: 640bp; Bet v 7 : 544bp
Figure 3 shows the testdigestion of isolated plasmids from six transformed colonies. All
vectors contain inserts with the correct size (Bet v 3: 640 bp, Lane 2-4; Bet v 7: 544 bp, Lane
5-7), indicating that the Bet v 3 and Bet v 7 genes were ligated successfully into the pHis
parallel 2 vector.
47
Constructs encoding the Bet v 4 and the Bet v 6 protein fused to a N-terminal His-tag were
already available.
Sequence of Bet v 4 :
>gi|809535|emb|X87153.1| B.verrucosa mRNA for BETV4 pollen allergen
CAACAGTGGAAACAAAAATGGCTGATGATCATCCACAGGACAAGGCTGAACGCGAGCGCATTTTCAAGCGCTTTGACGCCAATGGCGATGGTAAAATCTCTGCAGCAGAGCTTGGGGAGGCCTTGAAAACACTTGGCTCCATCACACCGGATGAGGTGAAACATATGATGGCCGAGATTGACACCGATGGCGACGGCTTCATTTCGTTCCAAGAGTTCACGGATTTTGGTCGTGCTAATCGTGGTTTACTAAAGGATGTTGCCAAGATATTTTAATGTCTCTGTCTCTTTCTCTTTTTTGTCATATTTTCATGTCATGATCTCCTTGTTTAGAGTGATTTATTTTCATGGCTATGGTCCGTTTGGATTTTTCTCATTATAGAATTATTTTTGGTAGTTCGACTGTCACCTCTTGTATTCTAATATCAATGGTGTTTGACCGTATTATTGTAACAAGAAAATGGTTCATCAGATTCGTGCATGTACATC
Sequence of Bet v 6 partial CDS:
>gi|4731375|gb|AF135127.1| Betula pendula isoflavone reductase homolog Bet v 6.0101 (BETV6) mRNA, partial cds
ATGGCTCACAAAAGCAAGATTCTGATCATCGGAGGCACCGGCTACATCGGAAAATTCATCGTGGAAGCAAGTGCAAAGTCTGGCCATCCCACCTTTGCTTTGGTCAGAGAGAGTACGGTCTCTGATCCCGTTAAGGGAAAACTTGTCGAGAAATTCAAGGGCTTAGGCGTCACTTTGCTCCATGGAGATCTGTATGACCATGAGAGTTTGGTAAAGGCGTTTAAGCAGGTGGACGTGGTGATATCGACGGTAGGCCACCTGCAGTTAGCAGATCAGGTCAAGATTATTGCTGCCATTAAAGAGGCTGGTAATATTAAGAGATTCTTCCCTTCGGAATTCGGAAACGACGTAGACCGTGTGCATGCTGTTGAGCCAGCAAAGACTGCATTTGCTACCAAGGCTGAAATCCGCCGCAAGACTGAGGCTGAAGGCATCCCCTACACTTATGTGTCATCCAATTTCTTCGCTGGATATTTTCTTCCTACGTTGGCACAACCAGGACTCACTTCTCCTCCTAGAGAGAAAGTCGTTATCTTCGGAGATGGAAATGCCAGGGCTGTTTTTAACAAGGAAGACGACATAGGAACTTACACAATTAGAGCTGTGGATGACCCAAGAACACTGAATAAGATAGTCTACATCAAGCCTGCCAAGAACATTTACTCATTCAATGAGATTGTTGCCCTTTGGGAGAAAAAGATTGGCAAAACCCTTGAGAAAATCTATGTTCCAGAGGAGAAACTTTTGAAGGACATCCAAGAGTCCCCAATTCCAATCAACGTGATATTAGCAATCAACCACTCAGTTTTTGTGAAGGGAGATCATACCAACTTTGAGATTGAGGCATCCTTCGGTGTGGAGGCCTCCGAGCTATACCCAGATGTCAAATACACCACAGTG
Testexpression of birch pollen allergens in E.coli BL21 (DE3)pLysS
In order to express the minor allergens, the isolated constructs were transformed in the
E.coli BL21(DE3)pLysS expression strain (Invitrogen GmbH, Lofer, Austria). To determine the
optimal expression conditions, testexpressions were performed varying in expression time
and temperature. Collected samples were applied to SDS-PAGE (15%, 15µl per slot) under
reducing conditions and stained with Coomassie brilliant blue R-250. For immunoblotting,
proteins were transfered onto a nitrocellulose membrane by means of tank blotting and
incubated with a Penta-his IgG1 antibody (Quiagen).
48
Testexpression of Bet v 3 at 37°C :
Bet v 3 (expected with a MW of 26 kDa) was found at all timepoints of IPTG induced
expression (Figure 4). High amounts of Bet v 3 were found 5h after the addition of IPTG.
After 5h of induced expression and cell lysis, the majority of the protein was found in the
urea-treated insoluble fraction.
The results of the western blot confirmed the data shown in Figure 3. Before the addition of
IPTG low amounts of Bet v 3 were detected (0h). After induction, the His- tagged Bet v 3
protein was expressed at all timepoints (1h-4h). Highest levels of Bet v 3 were found in the
insoluble fraction 5h after induction.
To maintain the natural conformation of the allergen it is important to avoid denaturation
steps during purification. Therefore, new testexpressions at 30°C and 18°C were performed
to express the protein in a soluble form.
Figure 4: Left: Expression of Bet v 3 at 37°C. Fractions obtained before (0h) and after addition of IPTG (1h - 5h) were analysed by means of SDS PAGE (15%) and coomassie staining. M, Fermentas PAGE Ruler
TM protein ladder. Sol, Insol,
soluble and insoluble fractions obtained after 5h expression and cell lysis. Insoluble fraction after treatment with 5M Urea. The red arrow indicates Bet v 3 with a molecular weight of 26 kDa
Right: Detection of HIS-tagged Bet v 3 by means of Western blotting. Fractions obtained before (0h) and after addition of IPTG (1h - 5h). Sol, Insol, soluble and insoluble fractions obtained after 5h expression and cell lysis. Insoluble fraction after treatment with 5M Urea. The red arrow indicates Bet v 3. M, Fermentas PAGE Ruler
TM protein ladder. A His-tagged protein
was used as a positive control. 2 seconds exposure to the fotofilm.
49
Testexpression of Bet v 3 at 30°C
The results of the testexpression at 30°C (Figure 5) were basically the same as at 37°C with
the majority of Bet v 3 as insoluble protein. Therefore a new testexpression at 18°C was
performed. The low temperature slows bacterial growth and protein expression which could
lead to a soluble expression of the protein.
Figure 5: : Left: Expression of Bet v 3 at 30°C. Fractions obtained before (0h) and after addition of IPTG (2h - 6h) were analysed by means of SDS PAGE (15%) and coomassie staining. M, Fermentas PAGE Ruler
TM protein ladder. Sol, Insol, soluble and insoluble
fractions obtained after 6h expression and cell lysis. Insoluble fraction after treatment with 5M Urea. The red arrow indicates Bet v 3 with a molecular weight of 26 kDa
Right: Detection of HIS-tagged Bet v 3 by means of Western blotting. Fractions obtained before (0h) and after addition of IPTG (2h - 6h). Sol, Insol, soluble and insoluble fractions obtained after 6h expression and cell lysis. Insoluble fraction after treatment with 5M Urea. The red arrow indicates Bet v 3 with a molecular weight of 26 kDa. M, Fermentas PAGE Ruler
TM protein ladder. A His-tagged
protein was used as a positive control. 1 minute exposure to the fotofilm.
50
Testexpression of Bet v 3 at 18°C
The testexpression of Bet v 3 at 18°C (Figure 6) also shows high amounts of Bet v 3 in the
insoluble fraction and only low amounts in the soluble fraction.
Unfortunately only small amounts of Bet v 3 were expressed as soluble protein under all
tested conditions. Therefore, Bet v 3 was purified from the insoluble fraction under
denaturing conditions.
Figure 6: Left: Expression of Bet v 3 for 20h at 18°C. Fractions obtained before (0h) and after addition of IPTG (5h, 20h) were analysed by means of SDS PAGE (15%) and coomassie staining. M, Fermentas PAGE Ruler
TM protein ladder. Sol, Insol, soluble
and insoluble fractions obtained after 20h expression and cell lysis. Insoluble fraction after treatment with 5M Urea. The red arrow indicates Bet v 3 with a molecular weight of 26 kDa
Right: Detection of HIS-tagged Bet v 3 by means of Western blotting. Fractions obtained before (0h) and after addition of IPTG (5h, 20h). Sol, Insol, soluble and insoluble fractions obtained after 20h expression and cell lysis. Insoluble fraction after treatment with 5M Urea. The red arrow indicates Bet v 3 with a molecular weight of 26 kDa. M, Fermentas PAGE Ruler
TM
protein ladder. A His-tagged protein was used as a positive control. 20 seconds exposure to the fotofilm.
51
Testexpression of Bet v 4 at 37°C
According to the immunoblot shown in Figure 7, the Bet v 4 protein (expected with a MW of
12 kDa) was found within the first 2 hours of IPTG-induced expression. The decreased
concentration of Bet v 4 at the later timepoints could result from degradation of the protein.
After 5h of induced expression and cell lysis, no his tagged protein was detected in the
soluble and insoluble fraction.
To limit degradation, the duration of the next testexpression was reduced to 2 hours at 37°C.
Figure 7: Left: Expression of Bet v 4 for 5h at 37°C. Fractions obtained before (0h) and after addition of IPTG (1h – 5h) were analysed by means of SDS PAGE (17%) and coomassie staining. M, Fermentas PAGE Ruler
TM protein ladder. Sol, Insol, soluble and insoluble
fractions obtained after 5h expression and cell lysis. Insoluble fraction after treatment with 5M Urea. The red arrow indicates Bet v 4 with a molecular weight of 12 kDa
Right: Detection of HIS-tagged Bet v 4 by means of Western blotting. Fractions obtained before (0h) and after addition of IPTG (1h – 5h). Sol, Insol, soluble and insoluble fractions obtained after 5h expression and cell lysis. Insoluble fraction after treatment with 5M Urea. The red arrow indicates Bet v 4 with a molecular weight of 12 kDa. M, Fermentas PAGE Ruler
TM protein ladder. A His-tagged
protein was used as a positive control. 20 seconds exposure to the fotofilm.
52
After 2h expression at 37°C the majority of Bet v 4 was found in the soluble fraction (Figure
8), therefore the optimal conditions for the expression of Bet v 4 in E.coli were 2h at 37°C.
Figure 8: Left: Expression of Bet v 4 for 2h at 37°C. Fractions obtained before (0h) and after addition of IPTG (1h - 2h) were analysed by means of SDS PAGE (17%) and coomassie staining. M, Fermentas PAGE Ruler
TM protein ladder. Sol, Insol, soluble and insoluble fractions
obtained after 2h expression and cell lysis. Insoluble fraction after treatment with 5M Urea. The red arrow indicates Bet v 4 with a molecular weight of 12 kDa
Right: Detection of HIS-tagged Bet v 4 by means of Western blotting. Fractions obtained before (0h) and after addition of IPTG (1h – 2h). Sol, Insol, soluble and insoluble fractions obtained after 2h expression and cell lysis. Insoluble fraction after treatment with 5M Urea. The red arrow indicates Bet v 4 with a molecular weight of 12 kDa. M, Fermentas PAGE Ruler
TM protein ladder. SN, supernatant. A His-tagged
protein was used as a positive control. 20 seconds exposure to the fotofilm.
53
Testexpression of Bet v 6 at 37°C
Bet v 6 (expected with a MW of 36 kDa) was found at all timepoints of IPTG induced
expression (Figure 9). High amounts of Bet v 6 were found 2h after the addition of IPTG.
After 5h of induced expression and cell lysis, the majority of the protein was found in the
soluble fraction. Bet v 6 was also present in the urea-treated insoluble fraction.
The results of the western blot confirmed the data shown in Figure 9. Before the addition of
IPTG no Bet v 6 was detected (0h). After induction, His- tagged Bet v 6 was expressed well at
all time points (1h-4h). Highest amounts of Bet v 6 were found in the soluble fraction 4h
after induction. Thus, the optimal time period for the expression of Bet v 6 in E.coli was 4h-
5h at 37°C.
Figure 9: Left: Expression of Bet v 6 for 5h at 37°C. Fractions obtained before (0h) and after addition of IPTG (1h- 5h) were analysed by means of SDS PAGE (17%) and coomassie staining. M, Fermentas PAGE Ruler
TM protein ladder. Sol, Insol, soluble and insoluble
fractions obtained after 5h expression and cell lysis. Insoluble fraction after treatment with 5M Urea. The red arrow indicates Bet v 6 with a molecular weight of 36 kDa
Right: Detection of HIS-tagged Bet v 6 by means of Western blotting. Fractions obtained before (0h) and after addition of IPTG (1h - 4h). Sol, Insol, soluble and insoluble fractions obtained after 4h expression and cell lysis. Insoluble fraction after treatment with 5M Urea. The red arrow indicates Bet v 6 with a molecular weight of 36 kDa. M, Fermentas PAGE Ruler
TM protein ladder. A His-tagged
protein was used as a positive control. 20 seconds exposure to the fotofilm.
54
Testexpression of Bet v 7 at 37°C
Bet v 7 (expected with a MW of 23 kDa) was found in high amounts at all timepoints of IPTG
induced expression (Figure 10). After 5h of induced expression and cell lysis, the protein was
found in the soluble and urea treated, insoluble fraction.
The results of the western blot confirmed the data shown in Figure 10. Before the addition
of IPTG only low amounts of Bet v 7 were detected (0h). After induction, His- tagged Bet v 7
was expressed well at all timepoints (1h-5h). Sufficient amounts of Bet v 7 were found in the
soluble fraction, therefore the optimal time period for the expression of Bet v 7 in E.coli was
4h-5h at 37°C
Figure 10: Left: Expression of Bet v 7 for 5h at 37°C. Fractions obtained before (0h) and after addition of IPTG (1h - 5h) were analysed by means of SDS PAGE (17%) and coomassie staining. M, Fermentas PAGE Ruler
TM protein ladder. Sol, Insol, soluble and
insoluble fractions obtained after 5h expression and cell lysis. Insoluble fraction after treatment with 5M Urea. The red arrow indicates Bet v 7 with a molecular weight of 21 kDa
Right: Detection of HIS-tagged Bet v 7 by means of Western blot. Fractions obtained before (0h) and after addition of IPTG (1h – 5h). Sol, Insol, soluble and insoluble fractions obtained after 5h expression and cell lysis. Insoluble fraction after treatment with 5M Urea. The red arrow indicates Bet v 7 with a molecular weight of 21 kDa. M, Fermentas PAGE Ruler
TM protein ladder. A His-tagged
protein was used as a positive control. 30 seconds exposure to the fotofilm.
55
Large scale expression and affinity purification of recombinant birch pollen proteins
After determining the optimal expression conditions for each allergen, large scale protein
expressions with 2 L E.coli BL21(DE3)pLysS cultures were performed. The cultured cells were
broken up in lysis buffer and freeze-thaw cycles. Most proteins were purified from the
soluble fraction, only Bet v 3 was purified from the insoluble fraction using 5M Urea.
All his-tagged proteins were separated from the lysate using His-Trap FF crude 1 mL
columns. The column was equilibrated and loaded using the ÄKTATM prime protein
purification system. Bound proteins were eluted by an increasing imidazol gradient and
fractions were collected. These were separated by SDS-PAGE and detected by coomassie
staining.
Purification of Bet v 3:
HIS-tagged Bet v 3 with a molecular weight of 26 kDa was found in high concentrations in all
eluted frations as depicted in Figure 11. The fractions 1-24 were pooled.
Figure 11: Eluted fractions (1-30) were separated by SDS- PAGE (15%) and stained with coomassie brilliant blue. Loaded protein sample (Load) flow through (Flow) and wash fractions were also analysed. M, Fermentas PAGE Ruler
TM protein
ladder.
56
Purification of Bet v 4:
His-tagged Bet v 4 (12 kDa) was detected in all eluted fractions (Figure 12). The fractions 7-
20 contained high amounts of Bet v 4 and were pooled.
Purification of Bet v 6:
Highest concentrations of His-tagged Bet v 6 (36 kDa) were found in the eluted fractions 11-
20 shown in Figure 13. The fractions 15-24 contained pure Bet v 6 and were pooled.
Figure 12: Eluted fractions (1-28) were separated by SDS- PAGE (17%) and stained with coomassie brilliant blue. Loaded protein sample (Load) flow through (Flow) and wash fractions were also analysed. M, Fermentas PAGE Ruler
TM protein ladder.
Figure 13: Eluted fractions (1-24) were separated by SDS- PAGE and stained with coomassie brilliant blue. Loaded protein sample (Load) flow through (Flow) and wash fractions were also analysed. M, Fermentas PAGE Ruler
TM protein ladder.
57
Purification of Bet v 7:
High concentrations of His-tagged Bet v 7 (21 kDa) were found in the fractions 11-17 and
were pooled (Figure 14). These fractions contained Bet v 7 together with low amounts of
unknown proteins with higher molecular weight.
The pooled fractions from all purified proteins were dialyzed against either PBS or Sodium
phosphate buffer (100 mM pH=6), to remove toxic imidazol and to determine the optimal
storage conditions that prevent protein precipitation. Samples were dialysed in
semipermeable dialysis tubes with a cut off at 5-7kD.
For most proteins, dialysis against the Sodium phosphate buffer resulted in less protein
precipitation and thus higher protein stability as summarized in Table 6.
Figure 14: Eluted fractions (1-30) were separated by SDS- PAGE and stained with coomassie brilliant blue. Loaded protein sample (Load) flow through (Flow) and wash fractions were also analysed. M, Fermentas PAGE Ruler
TM protein ladder.
58
Figure 15 shows the purity of pooled protein fractions of all recombinant birch pollen
allergens after dialysis on a coomassie stained SDS-PAGE gel. Lanes loaded with Bet v 3, Bet v
6 and Bet v 7 show one single protein band with the expected size of 26 kDa, 36 kDa and 21
kDa, respectively. The lane loaded with Bet v 4 showed the expected band at 12 kDa and a
second band at approximately 20 kDa which is expected to be a dimer.
Figure 15: Purified recombinant birch pollen allergens separated by SDS-PAGE (15%) and coomassie stained. BP, birch pollen extract (50 µg), M, Fermentas PAGE Ruler
TM protein ladder.
59
Endotoxin removal and determination of endotoxin levels of recombinant proteins
Several allergen batches were purified from 2 L cultures and dialyzed against different
buffers as shown in Table 6. Endotoxins were removed from dialysed samples using
EndoTrap® red 1 mL columns (Hyglos GmbH, Germany). Protein concentrations were
determined using the Pierce Endogen BCA assay (Thermo Scientific Inc., Rockford, USA) and
endotoxin levels were assessed by chromogenic LAL assays.
Table 6: Summary of recombinant protein batches with expression time and temperature, fraction from which the protein was purified, dialysis buffer, protein concentration after purification and endotoxin level after LPS removal.
With the optimized expression protocols and optimal dialysis buffers it was possible to
produce all minor birch pollen allergens in sufficient amounts as shown in Table 6. The
endotoxin removal by the EndoTrap® red 1 mL columns effectively reduced LPS
concentrations to satisfactory levels, in all proteins.
60
Humoral and cellular characterization of minor birch pollen allergens
IgE binding capacity of recombinant allergens
The IgE reactivity of the recombinant allergens was analyzed by means of ELISA. Allergens
were coated on microtiter plates and incubated with sera from birch pollen-allergic patients.
Sera from non-allergic donors and patients solely sensitized to Bet v 1 served as negative
controls. Bound IgE Ab were detected using a murine anti-human IgE antibody.
All tested birch pollen-allergic patients displayed in Figure 16 and Figure 17 (P1, P2, P3, P6,
P7, P8) showed IgE-reactivity to birch pollen extract (BP).
Recombinant Bet v 3 and Bet v 4 were clearly recognized by IgE antibodies from patient 2
(Figure 17). Patient 6 showed weak IgE binding to Bet v 6 and Patient 7 showed clear IgE
binding to Bet v 6. Bet v 7 was recognized by IgE antibodies from patient 2 and patient 3.
Non-allergic individuals and buffer controls were negative to BP and all tested allergens.
These results prove, that all recombinant allergens have maintained their IgE-binding
capacity, indicating that these proteins have kept their natural conformation.
Figure 16: IgE reactivity to birch pollen extract (50 µl/mL) and Bet v 6 (5 µg/mL) of sera from three selected patients (P6-8), plasma from an allergic patient as positive control and plasma from a non allergic as negative control; OD= Optical density
61
Figure 17: IgE reactivity to birch pollen extract (50 µl/mL), Bet v 3, Bet v 4, and Bet v 7 (5 µg/mL) of sera from three birch pollen allergic patients (P1-3), plasma from an allergic patient as positive control (P 5) and plasma from a non allergic as negative control (P 4); OD= Optical density
62
Proliferative responses of PBMC to recombinant birch pollen allergens
Primary responses were performed to test the activating capacity of the recombinant
allergens on PBMCs. Allergens were incubated at different concentrations with PBMCs
isolated from birch pollen-allergic donors. BP and IL-2 served as positive controls.
Proliferation was measured by adding 3H thymidine during the last 16 hours of culture.
Proliferation was determined after 6 days. Stimulation indices (SI) were calculated as the
ratio between counts per minute (cpm) obtained in cultures stimulated with allergen and
cpm from cultures incubated in medium alone. A SI greater than 2 was regarded as positive.
Figure 18: Allergen induced T-cell proliferation. PBMCs isolated from 4 birch pollen-allergic donors were incubated for 7 days with titrated concentrations of recombinant allergens. Proliferation measured by
3H thymidine incorporation.
Results are mean values of triplicates; Black lines indicate the median; SI = stimulation index = stimulated/ unstimulated well;
BP extract was able to induce T-cell proilferation in all 4 patients (Figure 18). T-cells from two patients showed high responses with a SI > 5. Proliferative responses were dose dependend in all patients.
0
2
4
6
8
10
12
14
16
1 3 5 7 9 11
SI
[µg/well]
BP
Patient 1
Patient 2
Patient 3
Patient 4
63
Figure 19: Bet v 1-induced T-cell proliferation. PBMCs isolated from 4 birch pollen-allergic donors were incubated for 7 days with titrated concentrations of recombinant allergens. Proliferation measured by
3H thymidine incorporation.
Results are mean values of triplicates; Black lines indicate the median; SI = stimulation index = stimulated/ unstimulated well;
Incubation with the major Bet v 1 isoform rBet v 1.0101 induced T-cell proliferation in PBMCs from all patients under investigation (Figure 19). Overall, proliferative responses correlated with Bet v 1 concentration.
Figure 20: Bet v 3-induced T-cell proliferation. PBMCs isolated from 4 birch pollen-allergic donors were incubated for 7 days with titrated concentrations of recombinant allergens. Proliferation measured by
3H thymidine incorporation.
Results are mean values of triplicates; Black lines indicate the median; SI = stimulation index = stimulated/ unstimulated well;
0
2
4
6
8
0 1 2 3 4 5
SI
[µg/well]
Bet v 1
Patient 1
Patient 2
Patient 3
Patient 4
0
2
4
6
8
10
12
14
0 1 2 3 4 5
SI
[µg/well]
Bet v 3
Patient 1
Patient 2
Patient 3
Patient 4
64
Recombinant Bet v 3 induced a detectable T-cell response in 3 of 4 patients as shown in Figure 20. T-cells from two patients reacted with a SI < 5 and one patient showed no T-cell reactivity to Bet v 3 (SI < 2). No clear dose-dependency was observed.
Figure 21: Bet v 4- induced T-cell proliferation. PBMCs isolated from 4 birch pollen-allergic donors were incubated for 7 days with titrated concentrations of recombinant allergens. Proliferation measured by
3H thymidine incorporation.
Results are mean values of triplicates; Black lines indicate the median; SI = stimulation index = stimulated/ unstimulated well;
Incubation with recombinant Bet v 4 induced T-cell proliferation in all tested patients (Figure 21). Of note, 3 patients showed highest reactivity to low doses of Bet v 4 (1,25 µg/mL) whereas one patient responded to higher amounts (5 µg/mL), therefore no clear dose-dependency was observed.
65
Figure 22: Bet v 6-induced T-cell proliferation. PBMCs isolated from 4 birch pollen-allergic donors were incubated for 7 days with titrated concentrations of recombinant allergens. Proliferation measured by
3H thymidine incorporation.
Results are mean values of triplicates; Black lines indicate the median; SI = stimulation index = stimulated/ unstimulated well;
Recombinant Bet v 6 induced T-cell proliferation in 3 of 4 patients as shown in Figure 22. Two patients reacted to Bet v 6 with a SI > 4 , one patient reacted with a SI of 2 and one patient showed no reactivity to any concentration tested. The proliferative response correlated with the Bet v 6 concentration.
Figure 23: Bet v 7-induced T-cell proliferation. PBMCs isolated from 4 birch pollen-allergic donors were incubated for 7 days with titrated concentrations of recombinant allergens. Proliferation measured by
3H thymidine incorporation.
Results are mean values of triplicates; Black lines indicate the median; SI = stimulation index = stimulated/ unstimulated well;
0
2
4
6
8
10
12
0 1 2 3 4 5
SI
[µg/well]
Bet v 6
Patient 1
Patient 2
Patient 3
Patient 4
0
2
4
6
8
10
12
14
16
18
20
22
0 1 2 3 4 5
SI
[µg/well]
Bet v 7
Patient 1
Patient 2
Patient 3
Patient 4
66
Incubation with recombinant Bet v 7 induced remarkable T-cell proliferation in two patients
(SI > 10) and one patient reacted with an SI > 2 (Figure 23). T-cell proliferation correlated
with the concentration of Bet v 7 in the patients with strong responses. T-cells from the
patient with a weak response, responded only to low Bet v 7 concentrations. One patient
showed no T-cell reactivity to any concentration tested.
Together, PBMCs from 4 birch pollen-allergic patients were tested for proliferative T-cell
responses to recombinant Bet v 1, Bet v 3, Bet v 4, Bet v 6, Bet v 7 and birch pollen extract
(Figure 18-23). 50% of the individuals showed T-cell responses to all allergens. Birch pollen
extract, Bet v 1 and Bet v 4 induced T-cell proliferation in all patients under investigation.
Recombinant Bet v 3, Bet v 6 and Bet v 7 induced T-cell responses in 3 of 4 patients.
These results demonstrate the preserved T-cell activating capacity of the recombinant
allergens and their non-toxicity to T-cells.
67
Isolation and characterization of birch pollen specific T-cell clones
Allergen induced proliferation of T-cell clones
In total, 25 birch pollen-reactive T-cell clones (TCC) were established from birch pollen specific T-cell lines and tested for their reactivity to the individual recombinant allergens. TCCs with a stimulation index (SI) > 5 were considered as specific. A summary is shown in Table 7.
13/25 TCCs (52%) reacted to recombinant Bet v 1.0101, the most abundant form of the
major allergen and natural Bet v 1 (nBet v 1). Natural Bet v 1 is the allergen directly isolated
from birch pollen containing all isoforms.
2/25 TCCs (8%) reacted with nBet v 1 but were Bet v 1.0101 negative.
One TCC (4%) was specific for the recombinant minor allergen Bet v 2.
9/25 TCCs (36%) reacted to BP extract but were negative for all tested recombinant
allergens. One TCC also reacted to BP extract only and could not be tested with Bet v 3 and
Bet v 7 because these allergens weren’t available at that time.
68
Table 7: Proliferative response of birch pollen specific TCCs to birch pollen allergens; nBet v 1, natural Bet v 1; n.t.= not tested; *SI are shown;
69
To characterize Bet v 1- specific TCCs further, 12 TCCs reactive to natural Bet v 1 were tested
with several Bet v 1- isoforms available as recombinant proteins (Table 8). Moreover these
TCCs were stimulated with a pannel of 50 synthetic, overlapping dodeca peptides
representing the complete Bet v 1.0101 amino acid sequence (Table 8).
5/12 TCCs (42%) reacted to Bet v 1.0201
6/12 TCCs (50%) reacted to Bet v 1.1401
10/12 TCCs (83%) reacted to the Bet v 1 isoforms 1.0401, 1.0501, 1.0101 and 1.0601
The two clones specific for natural Bet v 1 only, didn’t react to any tested isoform. All tested
Bet v 1.0101 specific TCC were specific for one of the distinct T-cell activating regions in Bet v
1, described by Jahn-Schmid et al43. Figure 24 shows an alignment of the tested Bet v 1-
isoforms and the mapped T-cell activating regions.
The TCC P4 #46 showed a significantly lower reaction to Bet v 1.1001 compared to the other
tested isoforms. The alignment shows an exchange of leucine to methionine at the
recognized epitope in this isoform.
The clones #18, #247 and #352 from patient 3 showed a comparable reaction to all isoforms
and the alignment confirms the sequential identity of the recognized epitope.
The TCCs P3 #145, P3 #493, P1 #e and P1 #28 did not react to the isoforms Bet v 1.0201 and
Bet v 1.1401. Here the alignment shows exchanges from valine to methionine, proline to
alanine and isoleucine to leucine at the recognized epitopes in the non reactive isoforms
(compared to Bet v 1.0101).
The cross reactivity of the TCCs with the Bet v 1-isoforms could be explained by their
differing sequence homology at the recognized epitope (Figure 24). The data also indicates,
that clone #10 from Patient 2 is polyclonal because he reacted to two distant Bet v 1
epitopes.
70
Table 8: Epitope specificity and isoform reactivity of Bet v 1-specific TCCs; SI are shown
Figure 24: Alignment of the AA sequence of Bet v 1 isoforms. T-cell activating regions and important AA differences are highlighted.
71
Th subsets of allergen specific T-cell clones
Supernatants of 25 allergen-specific TCCs were assessed for the content of the signature
cytokines IL-4 (TH2) and IFN-γ (TH1) upon specific stimulation (Table 9). The ratio of the
determined TH subsets are shown in Figure 25.
12/25 TCCs (48%) were specific for Bet v 1. From these 12 clones:
5/12 TCCs (42%) were TH0 like cells.
1/12 TCCs (8%) belonged to the TH1 subset.
6/12 TCCs (50%) belonged to the TH2 subset.
2/25 TCCs (8%) responded to natural Bet v 1 but not to Bet v 1.0101. Both TCCs were TH1 like
cells.
10/25 TCCs (40%) were specific for BP extract only. From these 10 clones:
8/10 (80%) were TH0 like cells.
2/10 (20%) belonged to the TH1 subset.
None of the TCCs only specific for BP extract were TH2 like cells.
One TCC reacted to Bet v 2 and belonged to the TH1 subset.
These results, illustrated in Figure 25, show that a majority of the Bet v 1.0101 reactive
clones are TH2 like cells. In contrast, for TCCs non reactive to Bet v 1.0101 the dominant
subset were TH0 like cells and none of these clones belonged to the TH2 subset.
Figure 25: TH subset ratio in Bet v 1.0101 positive and negative TCCs. Subsets determined by key cytokines in the supernatant. TH2= IL-4 : IFNγ >5, TH1= IL-4 : IFNγ <0,2, TH0= IL-4 : IFNγ 0.2 to 5
72
Table 9: Cytokine patterns of allergen- stimulated TCCs; *Determination of the TH subset: TH2= IL-4 : IFNγ >5, TH1= IL-4 : IFNγ <0,2, TH0= IL-4 : IFNγ 0.2 to 5
73
Surface marker expression of allergen specific T-cell clones
The following surface markers were analysed on 19 TCCs by flow cytometry:
- CD3, CD4 and to select the TH cell population
- TCR α/β to determine the T-cell receptor form
- CLA (cutaneous lymphocyte associated antigen) to stain for skin homing T-cells
- CD161 and CCR6 to stain for memory T-cells
In addition, TCCs were stained for the expression of surface markers suggested to be specific
for TH1 and TH2 cells:
- T-cell immunoglobin domain, mucin domain 3 (TIM-3)64 and CCR565 for TH1 cells
- Chemoattractant receptor of TH2 cells (CrTh2)66 and CCR365 for TH2 cells
Figure 26 shows a representative example of one TCC analyzed by flow cytometry. This clone
was defined as CD4+ TCRα/β + CLA- CCR6- CD161- CrTh2+ CCR3- TIM3- CCR5-.
The results were then compared to the cytokine profile in the collected supernatants.
Figure 26: Surface marker expression of allergen-specific TCCs. The expression of CD4, TCR α/β, CLA, CCR6, CD161, CCR3,
CrTh2, TIM3 and CCR5 was analyzed by flow cytometry.
74
19 TCCs were characterized by flow cytometry as shown in Table 10. As expected, all TCCs
expressed the surface markers CD3, CD4 as well as TCR α/β (not shown) and none of the
tested TCC expressed CLA (not shown).
10 TCCs were of the TH0 subtype according to the cytokine data. From these 10 clones:
2/9 (22%) TCCs expressed CCR6 (1 TCC was not tested)
9/9 (100%) TCCs expressed CD161 (1 TCC was not tested)
2/9 (22%) TCCs expressed CCR6 and CD161
7/10 (70%) TCCs expressed CRTH2
1/10 (10%) TCCs expressed CCR3
1/10 (10%) TCCs expressed CRTH2 and CCR3
2/10 (20%) TCCs expressed TIM3
10/10 (100%) TCCs expressed CCR5
2/10 (20%) TCCs expressed TIM3 and CCR5
4 TCCs were of the TH1 subtype according to the cytokine data. From these 4 clones:
3/4 (75%) TCCs expressed CCR6
4/4 (100%) TCCs expressed CD161
3/4 (75%) TCCs expressed CCR6 and CD161
2/4 (50%) TCCs expressed CRTH2
1/4 (25%) TCCs expressed CCR3
1/4 (25%) TCCs expressed CRTH2 and CCR3
0/2 (0%) TCCs expressed TIM3 (2 TCCs were not tested)
2/2 (100%) TCCs expressed CCR5
0/2 (0%) TCCs expressed TIM3 and CCR5
5 TCCs were of the TH2 subtype according to the cytokine data. From these 5 clones:
0/5 (0%) TCCs expressed CCR6
5/5 (100%) TCCs expressed CD161
0/0 (0%) TCCs expressed CCR6 and CD161
4/5 (50%) TCCs expressed CRTH2
0/5 (25%) TCCs expressed CCR3
0/5 (25%) TCCs expressed CRTH2 and CCR3
1/2 (0%) TCCs expressed TIM3 (3 TCCs were not tested)
2/2 (100%) TCCs expressed CCR5 (3 TCCs were not tested)
1/2 (50%) TCCs expressed TIM3 and CCR5
75
However, the expression of surface markers did not correlate with the production of the
signature cytokines IL-4 (TH2) and IFNγ (TH1) .
In 9/19 (47%) cases the results from the TH1 and TH2 markers were inconclusive.
In 5/10 (50%) conclusive cases, the results from the surface markers didn’t correspond to the
cytokine patterns detected in the supernatants.
For example, CrTh2 was expressed in high levels (>50%) by 4 TCCs. One of them produced
low amounts of both signature cytokines and was therefore defined as TH0. One produced
more IFNγ than IL-4 and was considered a TH1 like clone. One TCC produced no IFNγ and low
amounts of IL-4 and the last one produced significant amounts of IL-4. Both were defined as
TH2 like clones.
Table 10: Surface marker expression of allergen specific TCCs. Numbers indicate the percentage of positive cells; n.t.= not tested
76
TCR family typing
The family type of the T-cell receptor α and β chain was determined from 13 TCCs to
confirm the monoclonality of the T-cell clones. Figure 27 shows one representative example
of a TCR family typing.
As seen in Table 11, 8/13 (62%) TCCs were monoclonal according to the TCR family typing. In
5/13 (38%) of the characterized T-cell clones, the ß chains consisted of two or more families
which indicated that the cultured cells originated from at least two cells.
The most frequent β-chain families were:
β2 (4/13 TCCs = 31%)
β14 (3/13 TCCs = 23%) β7 (2/13 TCCs = 15%) The most frequent α-chain families were: α18 and α4 (4/13 TCCs = 31%) α2 (3/13 TCCs = 23%) α1, α8 and α20 (2/13 TCCs =15%)
77
Figure 27: TCR family typing ß-chain of TCC P4 #46.M, 100bp marker; ßactin with (+) and without (-) template as control; Each lane represents one ß-chain family. Positive for ß-chain family 2.
Table 11: T-cell receptor family typing of allergen-specific TCCs. Isolated and transcribed cDNA from T-cell clones was used as a template for the PCR. TCC; TCCs expressing more than one β-chain families were considered as polyclonal
78
Discussion
The usage of allergen extracts and purified natural allergens for diagnosis and therapy of
type I allergy, bears several problems. Exact standardization, batch to batch variablilty and
sensitization of the patient with other allergens are some of them.6 Therefore, the
production and characterization of recombinant allergens plays an important role in the field
of allergology.
Previous studies have identified Bet v 3, Bet v 4, Bet v 6 and Bet v 7 as minor birch pollen
allergens through their ability to bind IgE antibodies from less than 50% of allergic patients.
The Ca-binding allergens Bet v 3 and Bet v 4 were discovered by Seiberler S. et al and
Twardosz et al. respectively, by IgE immunoscreening of a birch pollen cDNA expression
library.51,67 The influence of Ca2+ on IgE epitopes and their cross reactivity to other proteins
were tested by immunoblot and immunoblot inhibition analyses.57,68-70 Bet v 6 was
characterized by Karamloo et al. Cross-reactivity was asseseed by immunoblot inhibition
analyses and allergenicity was tested using immunoblot and basophil histamine release
experiments.58,59 The immunological cross reactivity to Bet v 7 was demonstrated in
immunoblot and ELISA inhibition experiments by Cadot et al.61,63
The present study focused on expression and purification of the recombinant minor
allergens Bet v 3, Bet v 4, Bet v 6 and Bet v 7 and their humoral and cellular characterization.
Expression of eukaryotic genes in prokaryotes often leads to the formation of so called
inclusion bodies. These protein aggregates can form due to differences in the procaryotic
microenvironment, the absence of folding mechanism or overexpression. The isolation of
these protein aggregates requires harsh denaturation steps which may result in the loss of
the native structure of the protein. The loss of correct protein folding is often accompanied
by a loss of IgE binding and therefore often has a direct impact on the allergenic
properties71. Therefore, the major goal was to express the minor allergens as soluble
recombinant proteins.
This aim was successfully achieved for Bet v 4, Bet v 6 and Bet v 7 (Figure 7-10). Although Bet
v 3 was expressed under several different conditions (Figure 4-6) only small amounts were
obtained as soluble protein. Therefore, Bet v 3 was purified from the insoluble fraction
under denaturing conditions.
All His-tagged recombinant allergens were purified by Ni- affinity chromatography (Figure
11-15) and rebuffered by dialysis to avoid interference of imidazol with downstream
applications. Dialysis against sodium phosphate buffer showed the least protein
precipitation and thus higher protein stability for most proteins (Table 6).
79
To eliminate LPS-related effects in cell culture experiments, LPS concentrations were
successfully reduced to negligible levels (Table 6).
Allergen recognition by IgE antibodies from allergic patients is an indicator for allergenicity
and correct protein folding. Therefore, IgE binding to all minor allergens was assessed by
ELISA experiments with sera from birch pollen allergic patients (Figure 16, 17). Only sera
from patients with high CAP classes were used which makes statements on the prevalence of
the allergens impossible. However, all recombinant proteins were recognized by IgE
antibodies, indicating the correct folding of the allergens. These results were particularly
important to prove the remaining IgE binding capacity of the Bet v 3 protein after the
denaturation steps included in the isolation.
The minor allergens Bet v 3-7 have mostly been characterized at the molecular level in
previous studies51-61,63. In this study we additionally wanted to test their T-cell activating
capacity. For this purpose, we employed PBMC and allergen-specific TCCs expanded from
peripheral blood of birch pollen allergic patients.
Studying the proliferative responses of PBMCs to recombinant allergens confirms their T-cell
activating capacity and ensures that they are not toxic for T-cells. All recombinant minor
allergens were able to induce proliferation in PBMCs from birch pollen allergic patients.
It is still not known, why an overwhelming majority of BP allergic patients are sensitized to
Bet v 132. All allergens showed comparable PBMC responses when used in high
concentrations (ranging from 25 µg/mL to 3,1 µg/mL). A major difference between major
and minor allergens ist their abundance in birch pollen. Bet v 1 accounts for 10% of the total
protein content in B. pendula pollen as shown in Figure 131. The high quantity of Bet v 1
inhaled each spring might increase the chances of T- and B- cell responses. Additionally the
low abundance of minor allergens in birch pollen could be the cause of the low sensitization
rate in allergic patients.
In experiments with PBMCs or T-cell lines, antigen specific proliferation often originates from
a small number of specific T-cells. T-cell cloning is an important system to characterize these
cells that are potential targets for therapeutic interventions in allergic diseases. It allows the
analysis of the cytokine response and the expression of surface markers of one TCC specific
for one epitope. On the downside, large numbers of TCC must be generated to draw proper
conclusions.
We isolated BP-specific TCCs from allergic patients using BP extract. The majority (52%) were
specific for Bet v 1. All tested TCC specific for the main isoform Bet v 1.0101, reacted to one
of the distinct T-cell-activating regions in Bet v 1, described by Jahn-Schmid et al.43. Their
cross reactivity with several Bet v 1-isoforms could be explained by their identical sequence
of the recognized T-cell epitope (Figure 24).
80
None of the TCCs reacted with the allergens Bet v 3-7 and only one TCC was specifc for Bet v
2. The concentration of the minor allergens in birch pollen and the sensitization rate of
allergic patients is very low compared to Bet v 1, therefore these results were not surprising.
Still 36% of all TCCs were not reactive to any of the tested allergens but responded to BP
extract. These clones might be specific for a yet unknown protein in birch pollen.
The ratio of TH1 and TH2 cells and their produced cytokines play a major role in allergic
diseases. In order to classify TCCs into TH1/TH2 cells, their cytokine patterns in response to
specific stimulation were measured and the TH subset was determined accordingly. The
majority (58%) of Bet v 1 specific TCCs were TH2–like cells. They expressed high levels of IL-4
and negligible levels of IFNγ. No Bet v 1-specific TCC belonged to the TH1 subset and the
remaining 42% were TH0 like cells. In contrast, Bet v 1-negative, birch pollen-reactive TCCs
belonged mostly to the TH0 subset (80%), synthesizing comparable levels of IL-4 and IFNγ.
The remaining 20% were TH1 like cells. According to the present data it might be possible
that the specificity of T-cells to the major allergen Bet v 1 correlates with an increased
differentiation of T-cells to the TH2 subset.
Allergen-specific TCCs are very suitable to characterize the expression of homing markers
and surface markers defining their subset. All clones expressed the coreceptor CD4+ as well
as CD3 and TCRα/β defining them as T-helper cells with a α/β TCR. None of the clones
expressed the skin homing marker CLA which was expected, as none of the patients showed
skin manifestations origining from an allergic disease.
We also tried to determine the phenotype of TCCs by specific markers for TH-subsets. The
surface markers TIM-3 and CCR5 are preferentially expressed by TH1 as cited by Sabatos et
al. and Bonecci et al. respectively64,65. CrTH2 and CCR3 were used to determine Th2 cells by
Cosimi et al. and Bonecci et al. respectively65,66. Unfortunately the results were often
inconclusive and contradictive to the cytokine levels measured in the supernatant.
Therefore, we decided to rely solely on the cytokine-levels for the determination of the TH
subtype.
After the limiting dilution steps during T-cell cloning, it is possible to have different cells in
the same well or clones of the same T-cell in different wells. To adress this problem,
hypervariable regions of the TCR α and β chain were mapped by a PCR-based method to
fingerprint each TCC (Table 11). This was especially important for the discrimination of
clones that could not be distinguished by their cytokine levels or allergen specificity.
In summary, I was able to produce endotoxin-free batches (>5 mg) of recombinant Bet v 3,
Bet v 4, Bet v 6 and Bet v 7 with confirmed IgE reactivity. For the first time this study
demonstrates the T-cell stimulating capacity of these minor allergens. Now we are equipped
with a pannel of characterized minor allergens which will help to examine the differences
between Bet v 1 and minor allergens. Furthermore it is now possible to determine their
prevalence of recognition in a large population of allergic patients. Although no TCC specific
81
for the characterized allergens was isolated in this study, the stored TCC are valuable in the
search for new proteins with immunological value in birch pollen.
82
References
1. Valenta, R. The future of antigen-specific immunotherapy of allergy. Nat Rev Immunol 2, 446-53 (2002).
2. Erler, A. et al. Proteomic profiling of birch (Betula verrucosa) pollen extracts from different origins. Proteomics 11, 1486-98 (2011).
3. Canis, M., Groger, M., Becker, S., Klemens, C. & Kramer, M.F. Recombinant marker allergens in diagnosis of patients with allergic rhinoconjunctivitis to tree and grass pollens. Am J Rhinol Allergy 25, 36-9 (2011).
4. Vieths, S., Scheurer, S. & Ballmer-Weber, B. Current understanding of cross-reactivity of food allergens and pollen. Ann N Y Acad Sci 964, 47-68 (2002).
5. Sekerkova, A. & Polackova, M. Detection of Bet v1, Bet v2 and Bet v4 specific IgE antibodies in the sera of children and adult patients allergic to birch pollen: evaluation of different IgE reactivity profiles depending on age and local sensitization. Int Arch Allergy Immunol 154, 278-85 (2011).
6. Larche, M., Akdis, C.A. & Valenta, R. Immunological mechanisms of allergen-specific immunotherapy. Nat Rev Immunol 6, 761-71 (2006).
7. Abbas, A.K. Cellular and molecular immunology / Abul K. Abbas, Andrew H. Lichtman, Jordan S. Pober. (2007).
8. Minnicozzi, M., Sawyer, R.T. & Fenton, M.J. Innate immunity in allergic disease. Immunol Rev 242, 106-27 (2011).
9. Kamradt, T. & Ferrari-Kuhne, K. [Adaptive immunity]. Dtsch Med Wochenschr 136, 1678-83 (2011).
10. Chen Dong, G.J.M. T cells: the usual subsets. Nature reviews immunology (2010).
11. Thieu, V.T. et al. Signal transducer and activator of transcription 4 is required for the transcription factor T-bet to promote T helper 1 cell-fate determination. Immunity 29, 679-90 (2008).
12. Yagi, R., Zhu, J. & Paul, W.E. An updated view on transcription factor GATA3-mediated regulation of Th1 and Th2 cell differentiation. Int Immunol 23, 415-20 (2011).
13. Piccinni, M.P., Maggi, E. & Romagnani, S. Environmental factors favoring the allergen-specific Th2 response in allergic subjects. Ann N Y Acad Sci 917, 844-52 (2000).
83
14. Dardalhon, V. et al. IL-4 inhibits TGF-beta-induced Foxp3+ T cells and, together with TGF-beta, generates IL-9+ IL-10+ Foxp3(-) effector T cells. Nat Immunol 9, 1347-55 (2008).
15. Veldhoen, M. et al. Transforming growth factor-beta 'reprograms' the differentiation of T helper 2 cells and promotes an interleukin 9-producing subset. Nat Immunol 9, 1341-6 (2008).
16. Schmitt, E. et al. IL-9 production of naive CD4+ T cells depends on IL-2, is synergistically enhanced by a combination of TGF-beta and IL-4, and is inhibited by IFN-gamma. J Immunol 153, 3989-96 (1994).
17. Ouyang, W., Kolls, J.K. & Zheng, Y. The biological functions of T helper 17 cell effector cytokines in inflammation. Immunity 28, 454-67 (2008).
18. Ivanov, II et al. The orphan nuclear receptor RORgammat directs the differentiation program of proinflammatory IL-17+ T helper cells. Cell 126, 1121-33 (2006).
19. Eyerich, S. et al. Th22 cells represent a distinct human T cell subset involved in epidermal immunity and remodeling. J Clin Invest 119, 3573-85 (2009).
20. Fujita, H. et al. Human Langerhans cells induce distinct IL-22-producing CD4+ T cells lacking IL-17 production. Proc Natl Acad Sci U S A 106, 21795-800 (2009).
21. Meltzer, E.O. Quality of life in adults and children with allergic rhinitis. J Allergy Clin Immunol 108, S45-53 (2001).
22. Helen Chapel, M.H., Siraj Misbah. Essentials of Clinical Immunology,DNA Vaccines Methods and Protocols,Bioinformatics Methods and Protocols. (2000).
23. Durham, S.R., Gould, H.J. & Hamid, Q.A. Local IgE production in nasal allergy. Int Arch Allergy Immunol 113, 128-30 (1997).
24. Florido, J.F. et al. High levels of Olea europaea pollen and relation with clinical findings. Int Arch Allergy Immunol 119, 133-7 (1999).
25. Ronmark, E., Perzanowski, M., Platts-Mills, T. & Lundback, B. Different sensitization profile for asthma, rhinitis, and eczema among 7-8-year-old children: report from the Obstructive Lung Disease in Northern Sweden studies. Pediatr Allergy Immunol 14, 91-9 (2003).
26. Eisenbarth, S.C. et al. Lipopolysaccharide-enhanced, toll-like receptor 4-dependent T helper cell type 2 responses to inhaled antigen. J Exp Med 196, 1645-51 (2002).
27. Holgate, S.T. Novel targets of therapy in asthma. Curr Opin Pulm Med 15, 63-71 (2009).
28. Breiteneder, H. et al. The gene coding for the major birch pollen allergen Betv1, is highly homologous to a pea disease resistance response gene. Embo J 8, 1935-8 (1989).
84
29. Wensing, M. et al. IgE to Bet v 1 and profilin: cross-reactivity patterns and clinical relevance. J Allergy Clin Immunol 110, 435-42 (2002).
30. Geroldinger-Simic, M. et al. Birch pollen-related food allergy: clinical aspects and the role of allergen-specific IgE and IgG4 antibodies. J Allergy Clin Immunol 127, 616-22 e1 (2010).
31. Schenk, M.F. et al. Proteomic analysis of the major birch allergen Bet v 1 predicts allergenicity for 15 birch species. J Proteomics 74, 1290-300 (2011).
32. Jarolim, E. et al. Specificities of IgE and IgG antibodies in patients with birch pollen allergy. Int Arch Allergy Appl Immunol 88, 180-2 (1989).
33. Breiteneder, H. & Radauer, C. A classification of plant food allergens. J Allergy Clin Immunol 113, 821-30; quiz 831 (2004).
34. Breiteneder, H. et al. Four recombinant isoforms of Cor a I, the major allergen of hazel pollen, show different IgE-binding properties. Eur J Biochem 212, 355-62 (1993).
35. Mittag, D. et al. Ara h 8, a Bet v 1-homologous allergen from peanut, is a major allergen in patients with combined birch pollen and peanut allergy. J Allergy Clin Immunol 114, 1410-7 (2004).
36. Vanek-Krebitz, M. et al. Cloning and sequencing of Mal d 1, the major allergen from apple (Malus domestica), and its immunological relationship to Bet v 1, the major birch pollen allergen. Biochem Biophys Res Commun 214, 538-51 (1995).
37. Wiche, R. et al. Molecular basis of pollen-related food allergy: identification of a second cross-reactive IgE epitope on Pru av 1, the major cherry (Prunus avium) allergen. Biochem J 385, 319-27 (2005).
38. Scheurer, S. et al. Cross-reactivity within the profilin panallergen family investigated by comparison of recombinant profilins from pear (Pyr c 4), cherry (Pru av 4) and celery (Api g 4) with birch pollen profilin Bet v 2. J Chromatogr B Biomed Sci Appl 756, 315-25 (2001).
39. Hoffmann-Sommergruber, K. et al. Molecular characterization of Dau c 1, the Bet v 1 homologous protein from carrot and its cross-reactivity with Bet v 1 and Api g 1. Clin Exp Allergy 29, 840-7 (1999).
40. Kleine-Tebbe, J., Vogel, L., Crowell, D.N., Haustein, U.F. & Vieths, S. Severe oral allergy syndrome and anaphylactic reactions caused by a Bet v 1- related PR-10 protein in soybean, SAM22. J Allergy Clin Immunol 110, 797-804 (2002).
41. Oberhuber, C. et al. Characterization of Bet v 1-related allergens from kiwifruit relevant for patients with combined kiwifruit and birch pollen allergy. Mol Nutr Food Res 52 Suppl 2, S230-40 (2008).
85
42. Ferreira, F. et al. Dissection of immunoglobulin E and T lymphocyte reactivity of isoforms of the major birch pollen allergen Bet v 1: potential use of hypoallergenic isoforms for immunotherapy. J Exp Med 183, 599-609 (1996).
43. Jahn-Schmid, B. et al. Bet v 1142-156 is the dominant T-cell epitope of the major birch pollen allergen and important for cross-reactivity with Bet v 1-related food allergens. J Allergy Clin Immunol 116, 213-9 (2005).
44. Valenta, R. et al. Profilins constitute a novel family of functional plant pan-allergens. J Exp Med 175, 377-85 (1992).
45. Miralles, J.C., Caravaca, F., Guillen, F., Lombardero, M. & Negro, J.M. Cross-reactivity between Platanus pollen and vegetables. Allergy 57, 146-9 (2002).
46. Westphal, S. et al. Tomato profilin Lyc e 1: IgE cross-reactivity and allergenic potency. Allergy 59, 526-32 (2004).
47. Ebner, C. et al. Identification of allergens in fruits and vegetables: IgE cross-reactivities with the important birch pollen allergens Bet v 1 and Bet v 2 (birch profilin). J Allergy Clin Immunol 95, 962-9 (1995).
48. Hirschwehr, R. et al. Identification of common allergenic structures in hazel pollen and hazelnuts: a possible explanation for sensitivity to hazelnuts in patients allergic to tree pollen. J Allergy Clin Immunol 90, 927-36 (1992).
49. van Ree, R., Fernandez-Rivas, M., Cuevas, M., van Wijngaarden, M. & Aalberse, R.C. Pollen-related allergy to peach and apple: an important role for profilin. J Allergy Clin Immunol 95, 726-34 (1995).
50. Scheurer, S., Wangorsch, A., Haustein, D. & Vieths, S. Cloning of the minor allergen Api g 4 profilin from celery (Apium graveolens) and its cross-reactivity with birch pollen profilin Bet v 2. Clin Exp Allergy 30, 962-71 (2000).
51. Seiberler, S., Scheiner, O., Kraft, D., Lonsdale, D. & Valenta, R. Characterization of a birch pollen allergen, Bet v III, representing a novel class of Ca2+ binding proteins: specific expression in mature pollen and dependence of patients' IgE binding on protein-bound Ca2+. Embo J 13, 3481-6 (1994).
52. Hebenstreit, D. & Ferreira, F. Structural changes in calcium-binding allergens: use of circular dichroism to study binding characteristics. Allergy 60, 1208-11 (2005).
53. Moverare, R. et al. Different IgE reactivity profiles in birch pollen-sensitive patients from six European populations revealed by recombinant allergens: an imprint of local sensitization. Int Arch Allergy Immunol 128, 325-35 (2002).
54. Suphioglu, C., Ferreira, F. & Knox, R.B. Molecular cloning and immunological characterisation of Cyn d 7, a novel calcium-binding allergen from Bermuda grass pollen. FEBS Lett 402, 167-72 (1997).
86
55. Toriyama, K. et al. A cDNA clone encoding an IgE-binding protein from Brassica anther has significant sequence similarity to Ca(2+)-binding proteins. Plant Mol Biol 29, 1157-65 (1995).
56. Niederberger, V. et al. Calcium-dependent immunoglobulin E recognition of the apo- and calcium-bound form of a cross-reactive two EF-hand timothy grass pollen allergen, Phl p 7. Faseb J 13, 843-56 (1999).
57. Ferreira, F. et al. Characterization of recombinant Bet v 4, a birch pollen allergen with two EF-hand calcium-binding domains. Int Arch Allergy Immunol 118, 304-5 (1999).
58. Karamloo, F. et al. Phenylcoumaran benzylic ether and isoflavonoid reductases are a new class of cross-reactive allergens in birch pollen, fruits and vegetables. Eur J Biochem 268, 5310-20 (2001).
59. Karamloo, F. et al. Molecular cloning and characterization of a birch pollen minor allergen, Bet v 5, belonging to a family of isoflavone reductase-related proteins. J Allergy Clin Immunol 104, 991-9 (1999).
60. Wellhausen, A., Schoning, B., Petersen, A. & Vieths, S. IgE binding to a new cross-reactive structure: a 35 kDa protein in birch pollen, exotic fruit and other plant foods. Z Ernahrungswiss 35, 348-55 (1996).
61. Cadot, P. et al. Purification and characterization of an 18-kd allergen of birch (Betula verrucosa) pollen: identification as a cyclophilin. J Allergy Clin Immunol 105, 286-91 (2000).
62. Kullertz, G. et al. Stress-induced expression of cyclophilins in proembryonic masses of Digitalis lanata does not protect against freezing/thawing stress. Planta 208, 599-605 (1999).
63. Cadot, P., Nelles, L., Srahna, M., Dilissen, E. & Ceuppens, J.L. Cloning and expression of the cyclophilin Bet v 7, and analysis of immunological cross-reactivity among the cyclophilin A family. Mol Immunol 43, 226-35 (2006).
64. Sabatos, C.A. et al. Interaction of Tim-3 and Tim-3 ligand regulates T helper type 1 responses and induction of peripheral tolerance. Nat Immunol 4, 1102-10 (2003).
65. Bonecchi, R. et al. Differential expression of chemokine receptors and chemotactic responsiveness of type 1 T helper cells (Th1s) and Th2s. J Exp Med 187, 129-34 (1998).
66. Cosmi, L. et al. CRTH2 is the most reliable marker for the detection of circulating human type 2 Th and type 2 T cytotoxic cells in health and disease. Eur J Immunol 30, 2972-9 (2000).
67. Twardosz, A. et al. Molecular characterization, expression in Escherichia coli, and epitope analysis of a two EF-hand calcium-binding birch pollen allergen, Bet v 4. Biochem Biophys Res Commun 239, 197-204 (1997).
87
68. Tinghino, R. et al. Molecular, structural, and immunologic relationships between different families of recombinant calcium-binding pollen allergens. J Allergy Clin Immunol 109, 314-20 (2002).
69. Engel, E. et al. Immunological and biological properties of Bet v 4, a novel birch pollen allergen with two EF-hand calcium-binding domains. J Biol Chem 272, 28630-7 (1997).
70. Ledesma, A. et al. Are Ca2+-binding motifs involved in the immunoglobin E-binding of allergens? Olive pollen allergens as model of study. Clin Exp Allergy 32, 1476-83 (2002).
71. Chapman, M.D. et al. The European Union CREATE project: a model for international standardization of allergy diagnostics and vaccines. J Allergy Clin Immunol 122, 882-889 e2 (2008).
88
Appendix
Zusammenfassung
Allergische Erkrankungen haben in urbanen Regionen epidemische Ausmaße angenommen und beeinträchtigen die Lebensqualität der betroffenen Personen. Pollen von windbestäubenden Pflanzen wie der Europäischen Weiss-Birke (Betula verrucosa) gehören in Mittel- und Nordeuropa zu den potentesten Allergenquellen. Birkenpollen enthält das gut charakterisierte Hauptallergen Bet v 1 sowie mehrere Nebenallergene, die von weniger als 50% der Birkenpollen-Allergiker erkannt werden.
Diagnose und Therapie von Typ I Allergien hängen von der Qualität der verwendeten Allergenextrakte ab. Dabei können Defizite wie Chargenvariabilität oder unterschiedliche Konzentrationen verschiedener Komponenten auftreten. Diese können durch die Verwendung rekombinanter Allergene überwunden werden.
Die wichtigsten Ziele dieser Arbeit waren i) die Expression, Aufreinigung und Charakterisierung der Birkenpollen-Nebenallergene Bet v 3, Bet v 4, Bet v 6, Bet v 7 und ii) die Isolierung und Charakterisierung von T-Zell-Klonen (TCC) spezifisch für Birkenpollen Proteine.
Alle Nebenallergene wurden in E.coli mit einem His-Tag exprimiert und mittels Ni- Affinitätschromatographie aufgereinigt. Der LPS-Gehalt wurde auf vernachlässigbare Mengen reduziert. Die korrekte Faltung und Allergenizität wurde durch IgE ELISA-Experimente mit Seren von Birkenpollen-Allergikern getestet. Die Fähigkeit Birkenpollen-spezifische T-Zellen zu aktivieren wurde durch Proliferationsassays mit mononukleären Zellen des peripheren Blutes (PBMC), allergen-spezifischen T-Zell-Linien (TCL) und T-Zell-Klonen von Birkenpollen-Allergikern ermittelt. Alle rekombinanten Allergene konnten IgE-Antikörper binden und Proliferation in PBMC induzieren.
Allergen-spezifische TCC wurden aus Birkenpollen-spezifischen TCL isoliert und anhand von Proliferationsassays charakterisiert. Marker für T-Zellen und spezifische T-Zell Subtypen wurden mittels Durchflusszytometrie analysiert. Zusätzlich wurden Zytokinkonzentrationen in Überständen von aktivierten Allergen-spezifischen TCC durch Bead-Arrays bestimmt. Unsere Ergebnisse zeigen, dass die Mehrzahl der mit Birkenpollenextrakt expandierten TCC und TCL spezifisch für Bet v 1 waren und diese mehrheitlich zum TH2 Subtyp gehörten. TCC die nicht mit Bet v 1 reagierten gehörten großteils zum TH0 Subtyp. Ein TCC war spezifisch für das Nebenallergen Bet v 2. Kein Klon reagierte mit den rekombinanten Allergenen Bet v 3-7.
Im Rahmen dieser Diplomarbeit wurden endotoxinfreie Chargen von Bet v 3, Bet v 4, Bet v 6 und Bet v 7 hergestellt und deren IgE-Reaktivität bestätigt. Zum ersten Mal konnte die T-Zell-aktivierende Fähigkeit dieser Nebenallergene gezeigt werden.
89
In Zukunft könnten die produzierten und charakterisierten Allergene helfen, die immonologischen Unterschiede zwischen Bet v 1 und den identifizierten Nebenallergenen im Birkenpollen aufzuklären. Darüber hinaus könnten die eingefrorenen TCC hilfreich bei der Suche nach neuen Proteinen von immunologischen Wert im Birkenpollen sein.
90
Abstract
Allergic diseases have reached epidemic dimensions in urban areas and reduce the patients´
quality of life. Pollen from wind pollinated plants is among the most potent allergen sources.
Pollen from the European white birch Betula verrucosa contain the well characterized major
allergen Bet v 1 and several minor allergens which are recognized by less than 50% of birch
pollen-allergic patients.
Diagnosis and therapy of Type I allergy depends on the quality of the employed allergen
extracts. Disadvantages such as batch to batch variability or standardization of the
concentration of different components in allergen extracts may be overcome by the use of
recombinant allergens.
The major aims of this thesis were i) the expression, purification and characterization of the
minor birch pollen allergens Bet v 3, Bet v 4, Bet v 6, Bet v 7 and ii) the isolation and
characterization of T-cell clones (TCC) specific for proteins in birch pollen.
All minor allergens were expressed in E.coli with a His-tag and purified by Ni- affinity
chromatography. The LPS content was reduced to negligible levels. Correct folding and
allergenicity of the allergens was tested by IgE ELISA experiments conducted with sera from
birch pollen-allergic patients. The ability of the allergens to activate birch pollen-specific T-
cells was assessed in proliferation assays using peripheral blood mononuclear cells (PBMC),
allergen-specific T-cell lines (TCL) and TCC derived from birch pollen-allergic patients. All
recombinant minor allergens were able to bind IgE antibodies and induced proliferation in
PBMC from birch pollen-allergic patients.
Allergen specific TCC were expanded from birch pollen-specific TCL and characterized in
proliferation assays. Various subset-specific markers as well as molecules up regulated by
specific activation were analyzed by flow cytometry. Cytokine levels in the supernatants of
allergen-activated TCC were determined by cytokine bead arrays. Our results demonstrate
that the majority of the TCC isolated from TCL expanded with birch pollen extract were
specific for Bet v 1 and belonged to the TH2-like subset. TCC non-reactive with Bet v 1
belonged to the TH0-subset. None of the clones reacted with the recombinant minor
allergens Bet v 3-7. One TCC was found to be Bet v 2-specific.
In summary, endotoxin free batches of recombinant Bet v 3, Bet v 4, Bet v 6 and Bet v 7 were
produced and their IgE reactivity was confirmed. For the first time, the T-cell activating
capacity of these minor allergens was shown.
In the future, the produced and characterized allergens may help to examine the differences
between Bet v 1 and minor allergens. Furthermore, the stored TCC are valuable in the search
for new proteins with immunological value in birch pollen.
91
Abbreviations
Amp ampicillin APCs antigen presenting cells BCA bicinconinic acid cDNA complementary DNA CIAP Calf Intestine Alkaline Phosphatase kDa kilo Dalton
ddH2O double distilled water DMSO dimethyl sulfoxide DNA deoxyribonucleic acid EDTA ethylene-diamine-tetraacetate ELISA enzyme-linked immunosorbent assay EtBr Ethidium Bromide HIS histidine HRP horseradish peroxidase IFN γ Interferon γ Ig Immunoglobulin IPTG Isopropyl ß-D-1-thiogalactopyranoside
IS Immune system LPS lipopolysaccharide M molar MHC major histocompatibility complex mRNA messenger ribonucleic acid MW molecular weight Ni Nickel NK-cells natural killer cells PAGE polyacrylamide gelelectrophoresis
PAMPS pathogen associated molecular patterns
PBMCs peripheral blood mononuclear cells PCR polymerase chain reaction SDS sodium dodecyl sulfate SI stimulation index TCC T-cell clones TCL T-cell lines TCR T-cell receptor TLRs Toll like receptors TNFα Tumor necrosis factor α U Units
92
Restriction sites used in pHis parallel 2 vector:
4851 AGCAGCCCAG TAGTAGGTTG AGGCCGTTGA GCACCGCCGC CGCAAGGAAT 4901 GGTGCATGCA AGGAGATGGC GCCCAACAGT CCCCCGGCCA CGGGGCCTGC 4951 CACCATACCC ACGCCGAAAC AAGCGCTCAT GAGCCCGAAG TGGCGAGCCC 5001 GATCTTCCCC ATCGGTGATG TCGGCGATAT AGGCGCCAGC AACCGCACCT 5051 GTGGCGCCGG TGATGCCGGC CACGATGCGT CCGGCGTAGA GGATCGAGAT 5101 CTCGATCCCG CGAAATTAAT ACGACTCACT ATAGGGGAAT TGTGAGCGGA 5151 TAACAATTCC CCTCTAGAAA TAATTTTGTT TAACTTTAAG AAGGAGATAT 5201 ACATATGTCG TACTACCATC ACCATCACCA TCACGATTAC GATATCCCAA 5251 CGACCGAAAA CCTGTATTTT CAGGGCGCCA TGGGATCCGG AATTCAAAGG 5301 CCTACGTCGA CGAGCTCAAC TAGTGCGGCC GCTTTCGAAT CTAGAGCCTG 5351 CAGTCTCGAG CACCACCACC ACCACCACTG AGATCCGGCT GCTAACAAAG 5401 CCCGAAAGGA AGCTGAGTTG GCTGCTGCCA CCGCTGAGCA ATAACTAGCA 5451 TAACCCCTTG GGGCCTCTAA ACGGGTCTTG AGGGGTTTTT TGCTGAAAGG 5501 AGGAACTATA TCCGGAT
Restriction sites for BamHI and Not I in red
Media and buffer
10x TBE solution:
54 g Tris base
27.5 g Boric acid
20 mL 0.5 M EDTA solution / or: 4.65 g (Na4EDTA)
Fill up to 500 mL with ddH2O.
LB Amp medium:
5 g NaCl
10 g peptone
5 g yeast extract
Fill up to 1000 mL with ddH2O
Autoclave and when cooled down (handwarm) add 1 mL Amp (stock: 100 mg/mL) under
laminar flow/sterile conditions and keep in fridge.
LB medium:
5 g NaCL
10 g peptone
5 g yeast extract
Fill up to 1000 mL with ddH2O
Autoclave and store at RT.
93
LB Amp plates:
5 g NaCL
10 g peptone
5 g yeast extract
15 g Agar
Fill up to 100 mL with ddH2O
Autoclave and when cooled down (handwarm) add 1 mL Amp (stock: 100 mg/mL) and pour
plates under laminar flow/sterile conditions.
LB plates:
5 g NaCL
10 g peptone
5 g yeast extract
15 g Agar
Fill up to 100 mL with ddH2O
Autoclave and pour plates under laminar flow/sterile conditions.
10x PBS:
80 g NaCl
2 g KCl
14.4 g Na2HPO4
2.4 g KH2PO4
pH = 7.4 (HCl/NaOH)
Fill up to 1000 mL with ddH2O.
Coomassie Brilliant Blue: Destaining solution:
1 g Coomassie brilliant blue G-250 100 mL methyl alcohol
500 mL methyl alcohol 100 mL acetic acid
100 mL acetic acid 800 mL ddH2O
400 mL dd H2O
Dissolve Brilliant Blue in methyl alcohol first O/N
and then add the other substances because otherwise
the Brilliant Blue won’t dissolve properly.
Lysis buffer (50 mM Tris/HCl pH = 7.5, 0.5 M NaCl, 30 mM imidazole):
6.057 g Tris
29.22 g NaCl
2.04 g imidazole
Fill up to 1000 mL with ddH2O pH = 7.5 with HCl
94
Elution buffer (50 mM Tris/HCl pH = 7.5, 0.5 M NaCl, 500 mM imidazole):
6.057 g Tris
29.22 g NaCl
34.04 g imidazole
Fill up to 1000 mL with ddH2O pH = 7.5 with HCl
1 mg/mL DNase stock solution:
Buffer: 10 mM Tris/Hcl pH = 7.5, 150 mM NaCl, 1 mM MgCl
For 25 mL of buffer:
0.03 g Tris
0.219 g NaCl
0.00508 g MgCl
Dissolve 2 mg of DNase in 1 mL of buffer and when DNase has dissolved completely add 1
mL of glycerol.
Carbonate buffer (pH = 9.6):
1.965 g Na2CO3
2.645 g NaHCO3
Ad 500mL of ddH2O
Tissue culture media:
UCØ medium:
500 mL Ultra Culture medium (Lonza Group Ltd., Basel, Switzerland)
5 mL Glutamin (2.937 g/100 mL)
2.5 mL β-mercaptoethanol (35 μL/50 mL)
1 mL Gentamycin (10 g/118 mL)
N2 medium
500 mL RPMI 1640 buffered with 25mM Hepes (Gibco®,Invitrogen GmbH)
20% FCS (PAA Laboratories GmbH)
10% DMSO
1 mL Gentamycin (10 g/118 mL)
(Note: Add FCS to RPMI1640 medium and then add DMSO dropwise whilst gently shaking!)
95
Curriculum vitae
Personal data:
Name: Christian Walterskirchen
Date of Birth: 14. July 1985
Place of Birth: Vienna
Citizenship: Austrian
Education:
1995 – June 2003 Grammar school Franklinstraße 26
Oct. 2003 – Oct. 2004 Alternative service (Zivildienst) at an elementary school for handicapped children
Oct. 2004 – Aug. 2012 Diploma Programme in Biology, Division: Genetics and Microbiology) University of Vienna, Austria
Publications:
Kitzmüller C, Nagl B, Deifl S, Walterskirchen C, Jahn-Schmid B, Zlabinger GJ, Bohle B. Human blood basophils do not act as antigen-presenting cells for the major birch pollen allergen Bet v 1. Allergy. 2012 May
Congresses:
Dec. 3 – 5, 2010 Vienna Annual Meeting of the Austrian Society for Allergology and Immunology
C. Walterskirchen, S. Mutschlechner, S. Deifl, B. Nagl, S. Scheurer, G. Zlabinger, B. Bohle Identification and characterization of non-allergenic proteins in birch pollen Poster presentation